Therapeutic hpv16 vaccines

ABSTRACT

Provided is designer nucleic acid constructs and polypeptides that can be used as therapeutic vaccines against HPV16.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No. 16/058,411, filed Aug. 8, 2018, which is a continuation of U.S. patent application Ser. No. 15/601,278 filed May 22, 2017, issued as U.S. Pat. No. 10,071,151 on Sep. 11, 2018, which is a continuation of U.S. patent application Ser. No. 14/932,789, filed Nov. 4, 2015, issued as U.S. Pat. No. 9,701,721 on Jul. 11, 2017, which claims priority under the Paris Convention from European Patent Application Serial No. EP 14 191 660.1, filed Nov. 4, 2014, the entire contents of the aforementioned applications are incorporated herein by reference.

REFERENCE TO SEQUENCE LISTING SUBMITTED ELECTRONICALLY

This application contains a sequence listing, which is submitted electronically via EFS-Web as an ASCII formatted sequence listing with a file name “688097_278U3_sequence_listing” and a creation date of Jan. 21, 2020, and having a size of 31.2 KB. The sequence listing submitted via EFS-Web is part of the specification and is herein incorporated by reference in its entirety.

TECHNICAL FIELD

The disclosure relates to the field of biotechnology and medicine and, more in particular, to nucleic acid constructs and polypeptides that can be used in therapeutic vaccines against human papillomavirus type 16.

BACKGROUND

The family of human papillomaviruses (HPVs) include more than 100 types (also referred to as subtypes) that are capable of infecting keratinocytes of the skin or mucosal membranes. Over 40 types of HPV are typically transmitted through sexual contact and HPV infections of the anogenital region are very common in both men and women. Some sexually transmitted HPV types may cause genital warts. Persistent infections with “high-risk” HPV types (e.g., types 16, 18, 31, 45)—different from the ones that cause skin warts—may progress to precancerous lesions and invasive cancer, e.g., of the cervix, vulva, vagina, penis, oropharynx, and anus. The majority of HPV infections are spontaneously cleared within one to two years after infection. In healthy individuals circulating Th1- and Th2-type CD4+ T-cells specific for the viral early proteins E2, E6 and E7 of HPV-16 as well as E6-specific CD8+ T-cells, migrate into the skin upon antigenic challenge, indicating that successful defense against HPV-16 infection is commonly associated with a systemic effector T-cell response against these viral early antigens. In a minority (˜1%) of infected individuals, HPV infection persists, ultimately resulting in genital neoplastic lesions. Among the high-risk HPVs, HPV16 and HPV18 are the main cause of cervical cancer, together causing about 70% of the cases, and these two types also play a major role in other HPV-induced cancers such as anal and oropharyngeal cancer. Worldwide, HPV is one of the most important infectious agents causing cancer.

Vaccination against HPV is deemed a feasible strategy to reduce the incidence or effects of infection by HPV (van der Burg and Melief, 2011, Curr. Opinion Immunol. 23:252-257).

Prophylactic HPV vaccines based on virus-like particles (VLPs) formed by the (envelope) protein L1 of the HPV types 16 and 18, are very efficient in the prevention of persistent infection and the associated disease by HPV16 and HPV18. These vaccines are believed to provide sterile immunity via the induction of neutralizing antibodies against the L1 proteins. Addition of L1-based VLPs from additional high-risk HPV types may further increase the breadth of protection conferred by such vaccines.

However, while such vaccines can prevent initial infection (i.e., they result in prophylaxis), there is no evidence of a beneficial effect on established genital lesions caused by HPV16 and HPV18, so they are not considered therapeutic vaccines against HPV (Hildesheim et al., 2007, JAMA 298:743-53).

Despite the introduction of these prophylactic vaccines, large numbers of people have already had or are still at risk of having persistent high-risk HPV infections and, therefore, are still at risk of getting cancer. Therapeutic vaccines for the eradication of established HPV infections and associated diseases are an urgent unmet medical need.

Some attempts to address this need have been described. For example, clinical trials have been carried out with a variety of different vaccination strategies, such as a fusion protein consisting of a heat shock protein (Hsp) from Mycobacterium bovis and HPV-16 E7 or consisting of a fusion protein of E6, E7 and L2 from HPV-16 and HPV-18, chimeric L1-E7 VLPs, recombinant vaccinia viruses expressing either E6 and E7 of HPV-16 and HPV-18 or bovine papilloma virus E2, DNA vaccines expressing CTL epitopes of E6 and E7 of HPV-16 and HPV-18, a live-attenuated Listeria monocytogenes (Lm) that secretes the HPV-16 E7 antigen, and synthetic long-peptides (SLPs) comprising HPV-16 E6 and E7 peptides. While some of these approaches show some, but limited, clinical efficacy, most have failed, demonstrating that improvement of the current strategies is needed.

Integration of the early HPV proteins E6 and E7 is a necessary step in the process from infection to cancer and continuous expression of E6 and E7 is required for the maintenance of the neoplastic phenotype of cervical cancer cells. E6 and E7 are, therefore, considered good targets for therapeutic vaccination. As mentioned, some studies have shown that therapeutic vaccination of women infected with high-risk HPV can induce regression of existing lesions. Kenter et al. showed a durable and complete regression in 47% of patients having Vulvar Intraepithelial Neoplasia (VIN) using SLPs derived from the HPV16 E6 and E7 proteins and an adjuvant as a therapeutic vaccine (Kenter et al., 2009, N. Engl. J. Med. 361:1838-47). Similarly, a study in which a protein-based vaccine (TA-CIN, consisting of a fusion protein of HPV16 E6, E7 and L2) was combined with local immune modulation in VIN 2/3 patients, showed complete regression in 63% of patients (Daayana et al., 2010, Br. J. Cancer 102:1129-36). Possible drawbacks of the synthetic long peptides as a vaccine include manufacturability at large scale and costs associated therewith, the need for potentially reactogenic adjuvant and the associated adverse effects associated with immunization (especially pain and swelling). Due to the high level of discomfort it is not likely that SLPs will be used in early stage disease when the spontaneous clearance rate is still high. Similarly, due to the need for local imiquimod treatment in the case of TA-CIN treatment, tolerability is a significant issue as the majority of women experience local and systemic side effects lasting for the duration of imiquimod treatment, which may affect daily activities.

A possible alternative is to use nucleic acid based vaccination such as DNA vaccines or viral vaccines encoding the HPV E6 and/or E7 protein for vaccination.

However, the HPV E6 and E7 proteins have oncogenic potential and thus vaccination with vaccines that comprise nucleic acids encoding these proteins poses a risk of inducing cellular transformation due to the possibility of prolonged expression of the antigens.

Therefore, in case of genetic vaccination, non-oncogenic/detoxified versions of E6 and/or E7 can be used in order to exclude any risk of cellular transformation due to the vaccination. Loss of oncogenic potential of wild-type E6 and E7 is commonly achieved by deletion and/or substitution of residues known to be important for the function of these proteins (e.g., Smahel et al., 2001, Virology 281:231-38; Yan et al., 2009, Vaccine 27:431-40; Wieking et al., 2012, Cancer Gene Ther. 19:667-74; WO 2009/106362). However, a disadvantage of these approaches is that they carry the risk of removing important T-cell epitopes from and/or introducing new undesired T-cell epitopes into the proteins, and may thus not lead to the desired immune response.

In an alternative strategy to remove the oncogenic potential of HPV16 E6 and E7, shuffled versions (i.e., polypeptides wherein fragments of the wild-type protein are re-ordered) of the E6 and E7 proteins have been constructed (e.g., Ohlschlager et al., 2006, Vaccine 24:2880-93; Oosterhuis et al., 2011, Int. J. Cancer 129:397-406; Oosterhuis et al., 2012, Hum. Gen. Ther. 23:1301-12). However, these approaches would still require manufacturing, formulation and administration of multiple molecules to ensure inclusion of all possible epitopes of both the E6 and E7 proteins, resulting in sub-optimal logistics and relatively high costs, and moreover the strategies described introduce potentially strong non-natural epitopes that are not present in E6 and E7 and since immune responses could be diverted from relevant E6/E7 epitopes toward such non-natural epitopes, the described constructs may not have the optimal immunological characteristics.

Thus, there remains a need in the art for therapeutic vaccines against HPV, preferably having less of the drawbacks of the approaches described before.

BRIEF SUMMARY

Provided are nucleic acid molecules that encode polypeptides that comprise essentially all possible T-cell epitopes of HPV16 oncoproteins E6 and E7, but nevertheless have a strongly reduced (as compared to wild-type (“wt”) E6 and E7), up to non-detectable, transforming activity, by comprising fragments of the E6 and E7 proteins that have been re-ordered, while at the same time containing a minimized number of undesired neo-epitopes. This is in contrast to molecules previously presented by others.

Described is a nucleic acid molecule encoding a polypeptide comprising a sequence as set forth in SEQ ID NO:1.

The encoded polypeptide may further comprise a leader sequence.

In certain embodiments, the encoded polypeptide further comprises at least one epitope of a human papillomavirus (HPV) E2 protein, for example, an HPV16 E2 protein. The E2 protein may be mutated to decrease DNA binding, e.g., by a deletion or mutation(s) in its DNA binding domain. In certain embodiments, the encoded polypeptide comprises a sequence as set forth in SEQ ID NO:3 or SEQ ID NO:5.

In certain embodiments, the nucleic acid sequence is codon-optimized, e.g., for expression in human cells.

In certain embodiments, the nucleic acid molecule comprises a polynucleotide as set forth in SEQ ID NO:2, SEQ ID NO:4 , or SEQ ID NO:6.

Also provided is a vector comprising a nucleic acid molecule as described herein, wherein the molecule encoding the polypeptide is operably linked to a promoter.

In certain embodiments, the vector is a DNA vector such as a plasmid. In other embodiments, the vector is a viral vector, such as an MVA vector or a recombinant adenoviral vector. In certain preferred embodiments, the vector is a recombinant adenovirus.

In certain embodiments, the promoter in the vector is operably coupled to a repressor operator sequence, to which a repressor protein can bind in order to repress expression of the promoter in the presence of the repressor protein. In certain embodiments, the repressor operator sequence is a TetO sequence or a CuO sequence.

Also provided is a vaccine composition comprising a vector as described herein, and a pharmaceutically acceptable excipient.

Also provided is a method of inducing an immune response against HPV, in particular HPV16, in a subject, the method comprising administering to the subject a vaccine composition as described herein. Also provided is a vaccine as described herein for use in inducing an immune response against HPV, in particular HPV16.

In certain embodiments, the vaccine is administered to the subject more than once.

Also provided is a method for treating any of: persistent HPV infection (in particular persistent HPV16 infection), vulvar intraepithelial neoplasia (VIN), cervical intraepithelial neoplasia (CIN), vaginal intraepithelial neoplasia (VaIN), anal intraepithelial neoplasia (AIN), cervical cancer (such as cervical squamous cell carcinoma (SCC), oropharyngeal cancer, penile cancer, vaginal cancer, and/or anal cancer in a subject, the method comprising administering to the subject a vaccine as described herein. Also provided is a vaccine as described herein for use in treatment of any of: persistent HPV infection (in particular persistent HPV16 infection), vulvar intraepithelial neoplasia (VIN), cervical intraepithelial neoplasia (CIN), vaginal intraepithelial neoplasia (VaIN), anal intraepithelial neoplasia (AIN), cervical cancer (such as cervical squamous cell carcinoma (SCC), oropharyngeal cancer, penile cancer, vaginal cancer or anal cancer in a subject.

Also provided is a polypeptide comprising a sequence as set forth in SEQ ID NO:1, SEQ ID NO:3, or SEQ ID NO:5.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1: Expression of fusion proteins of HPV16 E6 and E7. HEK-293T cells were transiently transfected with DNA vectors expressing the transgenes indicated above the figure. Twenty-four hours after transfection the cells were harvested and cell extracts were analyzed by SDS-PAGE and Western blotting with an antibody against HPV16 E7 (upper panel). A loading control showing NF-kB (lower panel) confirms similar loading of cell lysates in all lanes. A molecular weight marker is indicated on the left. Expected sizes of the fusion proteins: E6E7SH approximately 38 kDa; E2E6E7SH and E6E7E2SH approximately 75 kDa, LSE2E6E7SH approximately 78 kDa.

FIGS. 2A-2C: Colony formation in soft agar. FIG. 2A: Schematic representation of the setup of the soft-agar assay. FIG. 2B: Representative microscopic images at 40× magnification of the cells in agar six weeks post-seeding. The white arrows highlight colonies observed in the E7 wt transfected cells. FIG. 2C: Colony quantification six weeks post-seeding in agar using the GELCOUNT™ and associated software. *: p<0.05 (Poisson regression model); **: non-inferior (generalized linear model with non-inferiority margin of 5%).

FIGS. 3A-3D: E6E7SH has lost E6 and E7 activities. FIG. 3A: Representative western blot demonstrating absence of p53 degradation by E6E7SH. Human p53 null NCI-H1299 cells were co-transfected with a plasmid expressing p53 in combination with a plasmid expressing HPV16 E6 wild-type, E6E7SH or the empty vector. Non-TF indicates non-transfected cells. Twenty-four hours after transfection cell lysates were prepared and 30 μg of total protein was loaded on gel. Upper panel—p53 staining, middle panel—E6 staining, lower panel—NF-kB staining (loading control). FIG. 3B: Quantification of p53 levels in four independent assays. The p53 signal was normalized to the NF-κB signal. FIG. 3C: Western blot demonstrating lack of pRb degradation by E6E7SH. pRb null Saos-2 cells were transfected with a plasmid expressing pRb in combination with a plasmid expressing HPV16 E7 wild-type, E6E7SH or the empty vector. Non-TF indicates non-transfected cells. Twenty-four hours after transfection cell lysates were prepared and 10 μg of total protein was loaded on gel. Upper panel—pRb staining, middle panel—E7 staining, lower panel—NF-κB staining (loading control). FIG. 3D: Quantification of pRb levels in four independent assays. The pRb signal was normalized to the NF-κB signal. *: p<0.05 (ANOVA models); **: non-inferior (testing was based on 95% CIs derived from ANOVA models. Non-inferiority margin was set at 75%).

FIG. 4: E6E7SH does not immortalize primary human epidermal keratinocytes. Primary human epidermal keratinocytes were transduced with lentiviruses encoding either the wild-type E6- and E7-encoding open reading frame of HPV16 (E6E7wt), the E6E7SH sequence or eGFP. Non-transduced donor cells were used as a control. Only expression of E6E7wt induces immortalization of primary keratinocytes as indicated by the extended lifespan and hTERT activation around day 200 (not shown). The cross symbol indicates that the cells died in senescence and could not be further cultured. For details see Example 2. Similar results were obtained in two additional donors (not shown).

FIGS. 5A and 5B: Immune response induced by E6E7SH after DNA immunization—IFNγ ELISPOT analysis. FIG. 5A: Immunization scheme. CB6F1 mice were immunized with DNA plasmids expressing E6E7SH or a plasmid expressing no transgene (control). Two weeks after immunization the mice were sacrificed and isolated splenocytes were stimulated overnight with 15mer peptide pools corresponding to E7. FIG. 5B: E7-specific immune responses in individual mice as measured by IFNγ ELISPOT assays are given as spot forming units (SFU) per 10⁶ splenocytes.

FIGS. 6A-6C: Immunogenicity of E6E7SH—IFNγ ELISPOT analysis. FIG. 6A: Immunization scheme. Mice were immunized with adenovectors with inserts as indicated. E7-specific responses at two weeks (FIG. 6B) and at eight weeks (FIG. 6C) were analyzed by IFNγ ELISPOT (represented as spot-forming units (SFU) per 10⁶ splenocytes). The closed circles represent mice immunized with a dosage of 1*10¹⁰ vp, and open circles represent mice immunized with 5*10⁹ vp. The black bar represents the geometric mean of the responses. The dotted line indicates the lower detection limit in the ELISPOT assay. ANOVA Post-hoc Bonferroni statistical analysis was performed on log transformed data. *: p<0.05. For details see Example 3.

FIGS. 7A and 7B: Immunogenicity of E2E6E7SH—E7-tetramer staining. FIG. 7A: Immunization scheme. CB6F1 mice were immunized with 1*10¹⁰ vp of adenovectors expressing the transgenes as indicated. Two weeks after immunization the mice were sacrificed and isolated splenocytes analyzed for the presence of CD8+ cells capable of interacting with E7₄₉₋₅₇-H2-Db tetramers (FIG. 7B). The percentage of E7-tetramer positive CD8+ T-cells is indicated on the y-axis. ANOVA Post-hoc Bonferroni statistical analysis was performed on log transformed data, the differences between the different E6E7SH variants were not statistically significant.

FIGS. 8A-8C: Immunogenicity of E2E6E7SH—IFNγ ELISPOT analysis. FIG. 8A: Immunization scheme. CB6F1 mice were immunized with adenovectors expressing the transgenes indicated below FIGS. 8B and 8C. Two weeks after immunization the mice were sacrificed and isolated splenocytes were stimulated overnight with 15mer peptide pools corresponding to E2 (FIG. 8B), E6 (not shown) or E7 (FIG. 8C). Responses are given as SFU per 10⁶ splenocytes. ANOVA Post-hoc Bonferroni statistical analysis was performed on log transformed data. The E2 response induced by Adenovectors encoding E2 alone is higher than the response induced by the polypeptides of the disclosure that include the E6 and E7 fragments. The difference is significant for E2 vs E2E6E7SH and E2 vs E6E7E2SH (*: p<0.05). ANOVA Post-hoc Bonferroni statistical analysis was performed on log transformed data.

FIGS. 9A-9C: Sustained responses in immunized mice. FIG. 9A: Immunization scheme. CB6F1 mice were immunized with 1*10¹⁰ vp of Ad35 vectors expressing variants LSE2E6E7SH, E2E6E7SH, E6E7SH, or with an adenovector not expressing a transgene (Empty). Blood samples were taken every two weeks to determine the percentage E7-specific CD8+ T-cells by tetramer staining. FIG. 9B: Immune responses two weeks after immunization. The vector including a leader sequence induced a higher response than vectors without the leader sequence; LSE2E6E7SH vs E2E6E7SH (*: p<0.05). FIG. 9C: Kinetics of the responses. ANOVA Post-hoc Bonferroni statistical analysis was performed on log transformed data of the week 2 data set. The E7 response induced by molecules including E2 tend to be higher compared to the molecule without E2, though the results were not statistically significant.

FIGS. 10A and 10B: Use of different Adenoviral vectors to boost immune responses. FIG. 10A: Immunization scheme. CB6F1 mice were immunized with an Ad26 vector expressing HPV16 E2E6E7SH (HPV16-Tx) or with an Ad26 vector expressing no transgene (empty). Two weeks later the immunizations were repeated with Ad35-based vectors as indicated below the figure. Four weeks after the second immunization the mice were sacrificed and blood samples were used to determine the percentage of E7-specific CD8+ T-cells by tetramer staining (FIG. 10B). * indicates the comparison of Ad26.HPV16-Tx/Ad35.HPV16-Tx versus Ad26.HPV16-Tx/Ad35.Empty, p<0.05 (student t-test on log transformed data, with alpha=0.01 for multiple comparisons).

FIGS. 11A and 11B: Cellular immunogenicity of E2E6E7SH in Rhesus macaques. FIG. 11A: Immunization scheme. Rhesus macaques were immunized at day 0: Eight animals received Ad26.HPV16-E2E6E7SH and two control animals received Ad26.Empty by intramuscular immunization (i.m.). A boost immunization was given (Ad26.HPV16-E2E6E7SH or Ad26.Empty) at 8 weeks. At 16 weeks, animals received a second boost immunization with Ad35 vectors expressing the same E2E6E7SH, while control animals received Ad35.Empty. The dose of adenovectors was 1*10¹¹ vp per immunization. Blood drawings were performed at several time points. FIG. 11B: Cellular immune responses in PBMCs were measured by IFNy ELISPOT. PBMCs were stimulated with peptide pools corresponding to HPV16 E2, E6 or E7 and the number of spot-forming units (SFU) in 1*10⁶ PBMCs are depicted. The empty control animal (n=2) showed no detectable response. For details see Example 4.

FIGS. 12A-12H: Therapeutic effect of Adenovectors expressing HPV16-E2E6E7SH. FIG. 12A: TC-1 injection and immunization scheme. CB6F1 mice were injected subcutaneously with 1*10⁵ TC-1 cells at day 0. After six days, when tumors were palpable, mice were immunized with two SLPs covering HPV16 E6 and E7 immunodominant epitopes (i.e., HPV16 E6, aa41-65 (KQQLLRREVYDFAFRDLCIVYRDGN; SEQ ID NO:18) and HPV16 E7 aa 43-77 (GQAEPDRAHYNIVTFCCKCDSTLRLCVQSTHVDIR; SEQ ID NO:19)) at 150 μg in a final volume of 200 μl 0.9% saline supplemented with 5 nmol ODN1826-CpG (FIG. 12B) or Ad26.HPV16-E2E6E7SH (FIG. 12C). Control mice received either CpG alone (FIG. 12D) or Ad26.Empty (FIG. 12E). All mice received a boost immunization at day 20. Mice that received Ad26 vectors in the prime immunization were subsequently immunized with the corresponding Ad35 vectors. The other mice received, SLP adjuvanted with CpG or CpG alone as in the prime immunizations. FIGS. 12B-12E: Tumor measurement in TC-1 injected mice. Tumor volume was calculated as (width²*length)/2. Mice were sacrificed when tumor volumes surpassed 1000 mm³. Two mice had to be sacrificed due to weight loss of more than 20% (indicated with asterisks). FIGS. 12F and 12G: Close up of FIGS. 12B and 12C for first 35 days. FIG. 12H: Survival after TC-1 injection. The survival of mice treated with Ad.HPV16-E2E6E7SH was significantly increased compared with mice immunized with SLP and CpG (Log-rank test p<0.05). Three mice immunized with the Ad.HPV16-E2E6E7SH were tumor free at the end of the experiment (at day 92).

FIGS. 13A and 13B: Adenoviral vectors carrying transgenes encoding either HPV Ag or LSE2E6E7SH show increased viral yields on cells capable of repressing transgene expression. FIG. 13A: Viral yield assay for Ad35 vectors. PER.C6®, PER.C6/CymR, and PER.C6/TetR cells were infected by Ad35 vectors carrying GFP-Luc- or HPVAg-encoding transgenes. These transgenes were driven by either CuO- or TetO-containing CMV promoters. Viral yields were determined four days after infection by an Ad35 hexon-specific qPCR-based method. FIG. 13B: Viral yield assay for Ad26 vectors. PER.C6® and PER.C6/TetR cells were infected by Ad26 vectors carrying GFP-Luc, HPVAg, or LSE2E6E7SH-encoding transgenes, which were all driven by a TetO-containing CMV promoter. Viral yields were determined three days after infection by an Ad26 hexon-specific qPCR-based method. For details see Example 6.

FIGS. 14A and 14B: Employment of a repressor system to repress transgene expression during vector production prevents transgene cassette instability in an adenoviral vector carrying an HPVAg-encoding transgene. An Ad35 vector expressing HPVAg under the control of CMVCuO was rescued by DNA transfection on either PER.C6® or PER.C6/CymR cell lines. Resultant viral plaques were picked—five per cell line—and used for consecutive infection rounds on the respective cell lines. FIG. 14A: Analysis of the integrity of the vector transgene cassette region by PCR after 10 viral passages. PCR products obtained from viral isolates passaged on PER.C6® and PER.C6/CymR are shown in the middle and right panels, respectively. The full-length-appearing PCR products obtained for PER.C6®-passaged viral isolates 1, 2, 4, and 5, and those seen for PER.C6/CymR-passaged isolates 1 to 5 were analyzed by Sanger DNA sequencing. Analysis of the chromatogram traces (not shown) revealed that all isolates grown on PER.C6®, but not those grown on PER.C6/CymR, contained either frameshifting small deletions or premature stop mutations within the coding sequence for HPVAg. FIG. 14B: Analysis of the ability of the vectors to express HPVAg after seven viral passages. A549 cells were transduced by the PER.C6®- and PER.C6/CymR-grown viral isolates and HPVAg expression was analyzed by Western Blot using an HPV16 E7-specific antibody. The predicted size for HPVAg is 83 kDa. For details see Example 6.

DETAILED DESCRIPTION

Provided is a nucleic acid molecule encoding a polypeptide comprising SEQ ID NO:1. The polypeptide is a fusion polypeptide, and is sometimes referred to herein as the polypeptide of the disclosure, or the fusion polypeptide of the disclosure. This polypeptide is useful to generate an immune response against the E6 and E7 proteins of HPV16, and thus the nucleic acid molecule can be used as a therapeutic vaccine to prevent persistent HPV16 infection, and diseases associated therewith.

The polypeptide of the disclosure is a carefully designed molecule that contains virtually the complete E6 and E7 amino acid sequences of HPV16 (it lacks only one amino acid from the C-terminus of the native HPV16 E6 protein) in the form of fragments that are re-ordered and partly overlapping such that (essentially) all T-cell epitopes of the HPV16 E6 and E7 protein are present. Earlier molecules with some potential as HPV vaccines have been described by others (e.g., Kenter et al., 2009, N. Engl. J. Med. 361:1838-47; Daayana et al., 2010, Br. J. Cancer 102:1129-36; Smahel et al., 2001, Virology 281:231-38; Yan et al., 2009, Vaccine 27:431-40; Öhlschlager et al., 2006, Vaccine 24:2880-93; Oosterhuis et al., 2011, Int. J. Cancer 129:397-406; EP1183368, WO 2013/083287), but each of these molecules has one or more drawbacks. The designer polypeptide molecules of the disclosure are advantageous in at least one and typically several aspects with respect to the approaches described earlier. In particular, advantages of the molecules and/or vectors of the present disclosure include: (i) they have a desired safety profile, as the nucleic acid has a strongly reduced (as compared to native E6 and E7 proteins), up to non-detectable, transforming activity; (ii) they are single nucleic acid molecules, which are easy to manufacture at industrial scale in an economically feasible manner, and do not pose logistic challenges unlike multiple molecule approaches; (iii) the encoded polypeptides comprise essentially all T-cell epitopes of the native HPV16 E6 and E7 proteins; (iv) the design of the encoded polypeptides has minimized the introduction of undesired potential strong neo-epitopes (i.e., epitopes not present in the native E6 and E7 proteins); and (v) in certain embodiments, they are not dependent on highly reactogenic adjuvants to raise a desired immune response. Thus, the molecules hereof represent a major step forward by combining various advantageous characteristics in a single design, and are excellent candidates primarily for therapeutic vaccination against HPV16. These molecules could also possibly work as prophylactic vaccines against HPV16, meaning that they are likely to prevent persistent infection with HPV16 of vaccinated subjects.

In certain embodiments, by careful design, the number of neo-epitopes with a length of nine amino acids with a predicted binding affinity <50 nM for the 20 most common HLA-A, 20 most common HLA-B and 20 most common HLA-C alleles was minimized to only one. This is a significant improvement over constructs described by others, which for a single shuffled E6 protein already contained more than 30 of such neo-epitopes, and which constructs will highly likely comprise even several more neo-epitopes in sequences that were appended to these constructs to prevent loss of epitopes (Öhlschlager et al., 2006, Vaccine 24:2880-93). Hence the constructs of the disclosure have a significantly improved immunologic profile since chances of an altered immune response as compared to native E6 and E7 have been minimized in the molecules of the disclosure, as compared to approaches described by others.

Skilled persons may, using routine techniques, make nucleotide substitutions that do not affect the polypeptide sequence encoded by the polynucleotides described to reflect the codon usage of any particular host organism in which the polypeptides are to be expressed. Therefore, unless otherwise specified, a “nucleotide sequence encoding an amino acid sequence” includes all nucleotide sequences that are degenerate versions of each other and that encode the same amino acid sequence. Nucleotide sequences that encode proteins and RNA may include introns.

In a preferred embodiment, the nucleic acid molecule encoding the polypeptide as described herein is codon optimized for expression in mammalian cells, preferably human cells. Methods of codon-optimization are known and have been described previously (e.g., WO 96/09378, the contents of which are incorporated herein by this reference). A sequence is considered codon optimized if at least one non-preferred codon as compared to a wild type sequence is replaced by a codon that is more preferred. Herein, a non-preferred codon is a codon that is used less frequently in an organism than another codon coding for the same amino acid, and a codon that is more preferred is a codon that is used more frequently in an organism than a non-preferred codon. The frequency of codon usage for a specific organism can be found in codon frequency tables, such as on the World Wide Web at kazusa.or.jp/codon. Preferably more than one non-preferred codon, e.g., more than 10%, 40%, 60%, 80% of non-preferred codons, preferably most (e.g., at least 90%) or all non-preferred codons, are replaced by codons that are more preferred. Preferably the most frequently used codons in an organism are used in a codon-optimized sequence. Replacement by preferred codons generally leads to higher expression.

Nucleic acid sequences can be cloned using routine molecular biology techniques, or generated de novo by DNA synthesis, which can be performed using routine procedures by service companies having business in the field of DNA synthesis and/or molecular cloning (e.g., GENEART®, GENSCRIPT®, INVITROGEN®, EUROFINS®).

It will be appreciated by a skilled person that changes can be made to a protein, e.g., by amino acid substitutions, deletions, additions, etc., e.g., using routine molecular biology procedures. Generally, conservative amino acid substitutions may be applied without loss of function or immunogenicity of a polypeptide. This can be checked according to routine procedures well known to the skilled person.

In certain embodiments, the encoded polypeptide as described herein further comprises a leader sequence, also referred to as signal sequence or signal peptide. This is a short (typically 5-30 amino acids long) peptide present at the N-terminus of the majority of newly synthesized proteins that are destined towards the secretory pathway. The presence of such a sequence may lead to increased expression and immunogenicity. Non-limiting examples that can be used are an IgE leader peptide (see, e.g., U.S. Pat. No. 6,733,994; e.g., having sequence MDWTWILFLVAAATRVHS (SEQ ID NO:7)) or a HAVT20 leader peptide (e.g., having sequence MACPGFLWALVISTCLEFSMA (SEQ ID NO:9)). One of these can optionally be added to the N-terminus of a polypeptide of the disclosure. In other embodiments, a polypeptide as described herein does not comprise a leader sequence.

Diverse types of HPV exist (over 120 types have been identified and are referred to by number), and generally for each type that needs to be covered by a vaccine, type-specific antigens may need to be incorporated in the vaccine, although for certain antigens some cross-reactivity might exist. Types 16, 18, 31, 33, 35, 39, 45, 51, 52, 56, 58, 59, 68, 73, and 82 are carcinogenic “high-risk” sexually transmitted HPVs and may lead to the development of cervical intraepithelial neoplasia (CIN), vulvar intraepithelial neoplasia (VIN), vaginal intraepithelial neoplasia (VaIN), penile intraepithelial neoplasia (PIN), and/or anal intraepithelial neoplasia (AIN). The HPV as described herein (i.e., the HPV from which the E6 and E7 fragments in the encoded polypeptide are derived) is HPV16. It can be used for subjects that are infected with HPV16. It may in certain embodiments also suitably be combined with vaccines against other HPV types. In certain embodiments, this combination is with a vaccine against HPV of a high risk type as identified above, e.g., with a vaccine against HPV18. In other embodiments, the vaccine of the disclosure is combined with a vaccine against one or more of HPV-18, -31, -33, -35, -39, -45, -51, -52, -56, -58, -59, -68, -73, or -82. Such combinations could, for instance, be used if the exact type of HPV infection is not yet certain, or if an immune response with a prophylactic effect is desired against more than one HPV type. Also combinations of the vaccines of the disclosure with vaccines against HPV types that cause genital warts, such as HPV6 and/or HPV11, are envisaged. Sequences of these HPV types and the proteins encoded thereby (e.g., E6, E7, E2) are available to the skilled person in public databases, such as the GenBank sequence database provided by the National Center for Technology Information (NCBI).

The polypeptide as described herein comprises SEQ ID NO:1, and in one embodiment the nucleic acid molecule as described herein comprises SEQ ID NO:2.

Sequences herein are provided from 5′ to 3′ direction or from N- to C-terminus, as custom in the art.

The polypeptide as described herein comprises the epitopes of HPV16 E6 and E7 proteins. In certain embodiments, the polypeptide as described herein further comprises (and hence the nucleic acid molecule encoding the polypeptide further encodes) at least one further antigen or epitope(s) of such further antigen. Such a further antigen preferably is an HPV antigen, preferably of the same HPV type as the E6 and E7 proteins in the polypeptide, i.e., HPV16. Such a further antigen can thus be an HPV protein or an immunogenic fragment thereof, and in certain embodiments comprises an E2 protein or a fragment thereof comprising at least one epitope of E2 of HPV, preferably from HPV16. Such further antigens or epitopes could be placed internally between two fragments of E6 and/or E7 in the polypeptide comprising SEQ ID NO:1, but preferably are fused N-terminally or C-terminally to the E6/E7 polypeptide comprising SEQ ID NO:1. Alternatively or in addition, amino acid sequences can be present that stimulate the immune response. Thus, in certain embodiments provided is nucleic acid molecules as described herein, encoding a polypeptide comprising SEQ ID NO:1, and wherein the polypeptide further comprises at least one other antigen, e.g., HPV E2 protein or at least one epitope, but preferably more epitopes, thereof. One advantage of the addition of E2 antigen for the instant disclosure is that E2 is known to be expressed early during infection/in low grade lesions where E6 and E7 expression is still very low. During the development towards cervical cancer E2 expression is lost and as a result E6 and E7 levels are increased (Yugawa and Kiyono, 2009, Rev. Med. Virol. 19:97-113). Combining epitopes from E2, E6 and E7 in one vaccine allows for treatment in a broad target group of patients, ranging from having persistent infection to invasive cervical cancer (or other HPV16-caused cancers). In certain embodiments, the E2 protein is a wild-type E2 protein. In certain other embodiments, the E2 protein has a deletion or one or more mutations in its DNA binding domain (as compared to a wild type E2 protein). The sequence of the HPV16 E2 protein (NP_041328.1) can be found in the NCBI protein database (on the World Wide Web at ncbi.nlm.nih.gov/protein) under number NP_041328.1. Several single amino acid changes in E2 such as G293V, K299M, or C300R in the C-terminal part of this protein are known to abrogate DNA binding. An advantage of using a variant or fragment of E2 that lacks DNA binding capacity is that it could prevent unpredictable transcriptional changes via direct binding to host cell DNA in the cells where it is expressed. The E2 protein or part or variant thereof can be added internally, but preferably to the N-terminus or to the C-terminus of the polypeptide of the disclosure having SEQ ID NO:1. In one embodiment, the nucleic acid molecule of the disclosure encodes a polypeptide comprising SEQ ID NO:3. In one embodiment thereof, the nucleic acid molecule of the disclosure comprises SEQ ID NO:4. In another embodiment, the nucleic acid molecule of the disclosure encodes a polypeptide comprising SEQ ID NO:5. In one embodiment thereof, the nucleic acid molecule of the disclosure comprises SEQ ID NO:6.

It is also possible to make further fusions of the designer polypeptides of the disclosure with further proteins, e.g., so called carrier proteins, such as Calreticulin, Mycobacterium Tuberculosis heat shock protein-70, IP10, or Tetanus toxin fragment C (see Oosterhuis et al., Human Gene Ther., 2012, supra, for more examples), which could further enhance the immune response to the HPV E6 and E7 (and optionally E2) epitopes. The disclosure thus also provides such further fusion proteins, and nucleic acids encoding such.

In certain embodiments, a nucleic acid molecule as described herein is incorporated into a vector. A “vector” as used herein, is typically a vehicle to artificially carry foreign genetic material into another cell, where it can be replicated and/or expressed, and as described herein can be any nucleic acid molecule that incorporates a nucleic acid molecule as described herein. These can be prepared according to routine molecular biology techniques such as cloning. Typically such vectors can be propagated in at least one type of suitable hosts such as bacteria, yeast, insect cells, mammalian cells, and the like. Four major types of vectors are plasmids, viral vectors, cosmids, and artificial chromosomes. The vector itself is generally a DNA sequence that consists of an insert (transgene; in the present disclosure the nucleic acid molecule encoding the fusion polypeptide of the disclosure) and a sequence that serves as the “backbone” of the vector. The purpose of a vector which transfers genetic information to another cell is typically to isolate, multiply, or express the insert in the target cell. Preferably, the sequence encoding the polypeptide is operably linked to a promoter in the vector. The term “operably linked” is intended to mean that the nucleotide sequence of interest is linked to the promoter in a manner that allows for expression of the nucleotide sequence (e.g., in a host cell when the vector is introduced into the host cell). Expression regulatory sequences can be operably linked to a transgene. In certain embodiments, vectors are designed for the expression of the transgene in the target cell, and generally have a promoter sequence that drives expression of the transgene. In certain embodiments, one or more of routinely used vector elements such as transcription terminator sequences, polyadenylation tail sequences, Kozak sequences, UTRs, origin of replication, multiple cloning sites, genetic markers, antibiotic resistance, and further sequences may be present, and the skilled person can design a vector such that it has the desired properties, e.g., for replication in certain cells for propagation and multiplication of the vector, and for expression of the transgene of the vector in target cells into which the vector is introduced. Vectors comprising the nucleic acid molecule encoding the fusion polypeptide as described herein, preferably designed for expression in mammalian cells, are suitable as vaccines as described herein. In certain embodiments, a vector as described herein is a plasmid, a cosmid, a yeast artificial chromosome, a bacterial artificial chromosome, a viral vector, or the like. The person skilled in the art is aware that various promoters can be used to obtain expression of a gene in host cells. Some well-known and much used promoters for expression in eukaryotic cells comprise promoters derived from viruses, such as adenovirus, e.g., the E1A promoter, promoters derived from cytomegalovirus (CMV), such as the CMV immediate early (IE) promoter (referred to herein as the CMV promoter) (obtainable, for instance, from pcDNA, INVITROGEN®), promoters derived from Simian Virus 40 (SV40) (e.g., obtainable from pIRES, cat.no. 631605, BD Sciences), and the like. Suitable promoters can also be derived from eukaryotic cells, such as metallothionein (MT) promoters, elongation factor la (EF-1α) promoter, ubiquitin C or UB6 promoter, actin promoter, an immunoglobulin promoter, heat shock promoters, and the like (see, e.g., WO 2006/048459). A non-limiting example of a suitable promoter for obtaining expression in eukaryotic cells is a CMV-promoter (U.S. Pat. No. 5,385,839), e.g., the CMV immediate early promoter, for instance, comprising nt. −735 to +95 from the CMV immediate early gene enhancer/promoter, e.g., a CMV promoter as provided herein with a sequence as set forth in SEQ ID NO:13. A polyadenylation signal, for example, the bovine growth hormone polyA signal (U.S. Pat. No. 5,122,458), may be present behind the transgene(s).

Further regulatory sequences may also be added. The term “regulatory sequence” is used interchangeably with “regulatory element” herein and refers to a segment of nucleic acid, typically but not limited to DNA, that modulate the transcription of the nucleic acid sequence to which it is operatively linked, and thus acts as a transcriptional modulator. A regulatory sequence often comprises nucleic acid sequences that are transcription binding domains that are recognized by the nucleic acid-binding domains of transcriptional proteins and/or transcription factors, enhancers or repressors, etc. For example, it is possible to operably couple a repressor sequence to the promoter, which repressor sequence can be bound by a repressor protein that can decrease or prevent the expression of the transgene in a production cell line that expresses this repressor protein. This may improve genetic stability and/or expression levels of the nucleic acid molecule upon passaging and/or when this is produced at high quantities in the production cell line. Such systems have been described in the art. For example, a regulatory sequence could include one or more tetracycline operon operator sequences (tetO), such that expression is inhibited in the presence of the tetracycline operon repressor protein (tetR). In the absence of tetracycline, the tetR protein is able to bind to the tetO sites and repress transcription of a gene operably linked to the tetO sites. In the presence of tetracycline, however, a conformational change in the tetR protein prevents it from binding to the operator sequences, allowing transcription of operably linked genes to occur. In certain embodiments, a nucleic acid molecule, e.g., when present in a recombinant adenovirus vector, of the present disclosure can optionally include tetO operatively linked to a promoter, such that expression of one or more transgenes is inhibited in recombinant adenoviruses that are produced in the producer cell line in which tetR protein is expressed. Subsequently, expression would not be inhibited if the recombinant adenovirus is introduced into a subject or into cells that do not express the tetR protein (e.g., international patent application WO 07/073513). In certain other embodiments, a nucleic acid molecule of the present disclosure, e.g., when present in a recombinant adenovirus, can optionally include a cumate gene-switch system, in which regulation of expression is mediated by the binding of the repressor (CymR) to the operator site (CuO), placed downstream of the promoter (e.g., Mullick et al., BMC Biotechnol. 2006 6:43). As used herein, the term “repressor,” refers to entities (e.g., proteins or other molecules) having the capacity to inhibit, interfere, retard and/or repress the production of heterologous protein product of a recombinant expression vector. For example, by interfering with a binding site at an appropriate location along the expression vector, such as in an expression cassette. Examples of repressors include tetR, CymR, the lac repressor, the trp repressor, the gal repressor, the lambda repressor, and other appropriate repressors known in the art. Examples of the use of the tetO/tetR operator/repressor system and of the CuO/CymR operator/repressor system are provided herein. Repression of vector transgene expression during vector propagation can prevent transgene instability, and may increase yields of vectors having a transgene of the disclosure during production. Hence, in some embodiments, the vectors of the disclosure have a promoter that can be repressed by binding of a repressor protein, e.g., by having a promoter that is operably coupled to a repressor operator sequence (e.g., in non-limiting embodiments, a TetO-containing sequence, e.g., the one set forth in SEQ ID NO:11, or a CuO-containing sequence, e.g., the one set forth in SEQ ID NO:12), to which a repressor protein (e.g., the TetR protein, e.g., having an amino acid sequence as set forth in SEQ ID NO:15, or the CymR protein, e.g., having an amino acid sequence as set forth in SEQ ID NO:17) can bind.

In certain embodiments, the vector is a plasmid DNA molecule, or a fragment thereof. These can be used for DNA vaccination. Other platforms are also possible for use as vectors, for instance, live-attenuated double-deleted Listeria monocytogenes strains.

In other embodiments, the vector is a recombinant viral vector, which may be replication competent or replication deficient. In certain embodiments, a viral vector comprises a recombinant DNA genome. In certain embodiments, a vector as described herein is, for instance, a recombinant adenovirus, a recombinant retrovirus, a recombinant pox virus such as a vaccinia virus (e.g., Modified Vaccinia Ankara (MVA)), a recombinant alphavirus such as Semliki forest virus, a recombinant paramyxovirus, such as a recombinant measles virus, or another recombinant virus. In certain embodiments, a vector as described herein is an MVA vector.

In preferred embodiments, a vector as described herein is a recombinant adenovirus. Advantages of adenoviruses for use as vaccines include ease of manipulation, good manufacturability at large scale, and an excellent safety record based on many years of experience in research, development, manufacturing and clinical trials with numerous adenoviral vectors that have been reported. Adenoviral vectors that are used as vaccines generally provide a good immune response to the transgene-encoded protein, including a cellular immune response. An adenoviral vector as described herein can be based on any type of adenovirus, and in certain embodiments is a human adenovirus, which can be of any serotype. In other embodiments, it is a simian adenovirus, such as chimpanzee or gorilla adenovirus, which can be of any serotype. In certain embodiments, a vector as described herein is of a human adenovirus serotype 5, 26 or 35. The preparation of recombinant adenoviral vectors is well known in the art. In certain embodiments, an adenoviral vector as described herein is deficient in at least one essential gene function of the E1 region, e.g., the E1a region and/or the E1b region, of the adenoviral genome that is required for viral replication. In certain embodiments, an adenoviral vector as described herein is deficient in at least part of the non-essential E3 region. In certain embodiments, the vector is deficient in at least one essential gene function of the E1 region and at least part of the non-essential E3 region.

Adenoviral vectors, methods for construction thereof and methods for propagating thereof, are well known in the art and are described in, for example, U.S. Pat. Nos. 5,559,099, 5,837,511, 5,846,782, 5,851,806, 5,994,106, 5,994,128, 5,965,541, 5,981,225, 6,040,174, 6,020,191, and 6,113,913, and Thomas Shenk, “Adenoviridae and their Replication,” M. S. Horwitz, “Adenoviruses,” Chapters 67 and 68, respectively, in Virology, B. N. Fields et al., eds., 3d ed., Raven Press, Ltd., New York (1996), and other references mentioned herein (each of which is hereby incorporated by this reference in its entirety). Typically, construction of adenoviral vectors involves the use of standard molecular biological techniques, such as those described in, for example, Sambrook et al., Molecular Cloning, a Laboratory Manual, 2d ed., Cold Spring Harbor Press, Cold Spring Harbor, N.Y. (1989), Watson et al., Recombinant DNA, 2d ed., Scientific American Books (1992), and Ausubel et al., Current Protocols in Molecular Biology, Wiley Interscience Publishers, NY (1995), and other references mentioned herein.

Particularly preferred serotypes for the recombinant adenovirus are human serotype 35 or human serotype 26. Preparation of rAd26 vectors is described, for example, in WO 2007/104792 and in Abbink et al., 2007 Virology 81:4654-63. Exemplary genome sequences of Ad26 are found in GenBank Accession EF 153474 and in SEQ ID NO:1 of WO 2007/104792. Preparation of rAd35 vectors is described, for example, in U.S. Pat. No. 7,270,811, in WO 00/70071, and in Vogels et al., 2003, J. Virol. 77:8263-71. Exemplary genome sequences of Ad35 are found in GenBank Accession AC_000019 and in FIG. 6 of WO 00/70071 (each of which is hereby incorporated by this reference in its entirety).

In certain embodiments, the adenovirus is replication deficient, e.g., because it contains a deletion in the E1 region of the genome. As known to the skilled person, in case of deletions of essential regions from the adenovirus genome, the functions encoded by these regions have to be provided in trans, preferably by the producer cell, i.e., when parts or whole of E1, E2 and/or E4 regions are deleted from the adenovirus, these have to be present in the producer cell, for instance, integrated in the genome thereof, or in the form of so-called helper adenovirus or helper plasmids. The adenovirus may also have a deletion in the E3 region, which is dispensable for replication, and hence such a deletion does not have to be complemented.

A producer cell (sometimes also referred to in the art and herein as “packaging cell” or “complementing cell”) that can be used can be any producer cell wherein a desired adenovirus can be propagated. For example, the propagation of recombinant adenovirus vectors is done in producer cells that complement deficiencies in the adenovirus. Such producer cells preferably have in their genome at least an adenovirus E1 sequence, and thereby are capable of complementing recombinant adenoviruses with a deletion in the E1 region. Any E1-complementing producer cell can be used, such as human retina cells immortalized by E1, e.g., 911 or PER.C6® cells (see U.S. Pat. No. 5,994,128), E1-transformed amniocytes (see EP Patent 1230354), E1-transformed A549 cells (see, e.g., WO 98/39411, U.S. Pat. No. 5,891,690), GH329:HeLa (Gao et al., 2000, Hum. Gene Ther. 11:213-19), 293, and the like (each of which is hereby incorporated by this reference in its entirety). In certain embodiments, the producer cells are, for instance, HEK293 cells, or PER.C6® cells, or 911 cells, or IT293SF cells, and the like. Production of adenoviral vectors in producer cells is reviewed in (Kovesdi et al., 2010, Viruses 2:1681-703).

In certain embodiments, an E1-deficient adenovirus comprises the E4-orf6 coding sequence of an adenovirus of subgroup C such as Ad5. This allows propagation of such adenoviruses in well-known complementing cell lines that express the E1 genes of Ad5, such as, for example, 293 cells or PER.C6® cells (see, e.g., Havenga et al., 2006, J. Gen. Virol. 87:2135-43; WO 03/104467, incorporated in its entirety by reference herein).

“Heterologous nucleic acid” (also referred to herein as “transgene”) in vectors of the disclosure is nucleic acid that is not naturally present in the vector, and according to the present disclosure the nucleic acid molecule encoding the fusion polypeptide of the disclosure is considered heterologous nucleic acid when present in a vector. It is introduced into the vector, for instance, by standard molecular biology techniques. It can, for instance, be cloned into a deleted E1 or E3 region of an adenoviral vector, or in the region between the E4 region and the rITR. A transgene is generally operably linked to expression control sequences. In preferred embodiments, the transgene is cloned into the E1-region of an adenoviral vector.

Production of vectors such as DNA vectors, or recombinant adenovirus vectors, can be performed according to various methods well known to the person skilled in the art. Generally, the production entails propagation in cultured cells to generate a substantial amount of vector material, followed by harvest of the vector from the cell culture, and typically followed by further purification of the vector to remove other substances and obtain purified vectors that can be formulated into pharmaceutical compositions (e.g., Hoganson et al., 2002, BioProcessing 1:43-8; Evans et al., 2004, J. Pharm. Sci. 93:2458-75). For example, methods for harvesting adenovirus from cultures of producer cells have, for instance, been extensively described in WO 2005/080556. For example, WO 2010/060719, and WO 2011/098592, both incorporated by reference herein, describe suitable methods for obtaining and purifying large amounts of recombinant adenoviruses.

In certain aspects, also provided is a polypeptide that is encoded by a nucleic acid molecule as described herein. Such a polypeptide comprises SEQ ID NO:1. In certain embodiments, such a polypeptide may comprise SEQ ID NO:3 or SEQ ID NO:5. The characteristics of such a polypeptide are as described above. Such a polypeptide can, for instance, be used directly as a vaccine against HPV.

The disclosure further provides vaccines comprising nucleic acid molecules, vectors or polypeptides as described herein, wherein embodiments for each of these aspects can include those as described above. In preferred embodiments, a vaccine as described herein comprises a nucleic acid molecule as described herein. In further preferred embodiments, the vaccine comprises a vector as described herein, preferably a DNA vector, an MVA vector, or a recombinant adenovirus vector.

In certain embodiments, a vaccine as described herein comprises further active ingredients, e.g., nucleic acid molecule encoding at least one epitope of E6 and/or E7 protein of at least one HPV type different from HPV16, e.g., a high risk HPV type such as HPV18, -31, -33, -35, -39, -45, -51, -52, -56, -58, -59, -68, -73, or -82.

The term “vaccine” refers to an agent or composition containing an active component effective to induce a prophylactic and/or therapeutic degree of immunity in a subject against a certain pathogen or disease, in this case therapeutically against HPV. The vaccine typically comprises the nucleic acid molecule, or vector, as described herein, and a pharmaceutically acceptable excipient. Upon administration to a subject, the polypeptide encoded by the nucleic acid molecule as described herein will be expressed in the subject, which will lead to an immune response towards E6 and/or E7 antigenic fragments that are present in the polypeptide. The advantage of the instant molecules is that essentially all T-cell epitopes of HPV16 E6 and E7 are present and thus a T-cell response to any epitope present in wild-type E6 or E7 can be mounted in the vaccine. Further, the vaccine has all the safety and efficacy advantages as outlined above for the nucleic acid molecules as described herein.

For administering to humans, the disclosure may employ pharmaceutical compositions comprising the vector and a pharmaceutically acceptable carrier or excipient. In the present context, the term “Pharmaceutically acceptable” means that the carrier or excipient, at the dosages and concentrations employed, will not cause any unwanted or harmful effects in the subjects to which they are administered. Such pharmaceutically acceptable excipients are well known in the art (see Remington's Pharmaceutical Sciences, 18th edition, A. R. Gennaro, Ed., Mack Publishing Company [1990]; Pharmaceutical Formulation Development of Peptides and Proteins, S. Frokjaer and L. Hovgaard, eds., Taylor and Francis [2000]; and Handbook of Pharmaceutical Excipients, 3rd edition, A. Kibbe, Ed., Pharmaceutical Press [2000]). An excipient is generally a pharmacologically inactive substance formulated with the active ingredient of a medication. Excipients are commonly used to bulk up formulations that contain potent active ingredients (thus often referred to as “bulking agents,” “fillers,” or “diluents”), to allow convenient and accurate dispensation of a drug substance when producing a dosage form. They also can serve various therapeutic-enhancing purposes, such as facilitating drug absorption or solubility, or other pharmacokinetic considerations. Excipients can also be useful in the manufacturing process, to aid in the handling of the active substance concerned such as by facilitating powder flowability or non-stick properties, in addition to aiding in vitro stability such as prevention of denaturation over the expected shelf life. The selection of appropriate excipients also depends upon the route of administration and the dosage form, as well as the active ingredient and other factors.

The purified nucleic acid molecule, vector or polypeptide preferably is formulated and administered as a sterile solution although it is also possible to utilize lyophilized preparations. Sterile solutions are prepared by sterile filtration or by other methods known per se in the art. The solutions are then lyophilized or filled into pharmaceutical dosage containers. The pH of the solution generally is in the range of pH 3.0 to 9.5, e.g., pH 5.0 to 7.5. The nucleic acid molecule or vector or polypeptide typically is in a solution having a suitable buffer, and the solution of vector may also contain a salt. Optionally stabilizing agent may be present, such as albumin. In certain embodiments, detergent is added. In certain embodiments, vaccine may be formulated into an injectable preparation. These formulations contain effective amounts of nucleic acid molecule, vector or polypeptide are either sterile liquid solutions, liquid suspensions or lyophilized versions and optionally contain stabilizers or excipients.

For instance, recombinant adenovirus vector may be stored in the buffer that is also used for the Adenovirus World Standard (Hoganson et al., 2002, Bioprocessing J. 1:43-8): 20 mM Tris pH 8, 25 mM NaCl, 2.5% glycerol. Another useful formulation buffer suitable for administration to humans is 20 mM Tris, 2 mM MgCl₂, 25 mM NaCl, sucrose 10% w/v, polysorbate-80 0.02% w/v. Another formulation buffer that is suitable for recombinant adenovirus comprises 10-25 mM citrate buffer pH 5.9-6.2, 4-6% (w/w) hydroxypropyl-beta-cyclodextrin (HBCD), 70-100 mM NaCl, 0.018-0.035% (w/w) polysorbate-80, and optionally 0.3-0.45% (w/w) ethanol. Obviously, many other buffers can be used, and several examples of suitable formulations for the storage and for pharmaceutical administration of purified vectors are known.

In certain embodiments, a composition comprising the vector further comprises one or more adjuvants. Adjuvants are known in the art to further increase the immune response to an applied antigenic determinant. The terms “adjuvant” and “immune stimulant” are used interchangeably herein, and are defined as one or more substances that cause stimulation of the immune system. In this context, an adjuvant is used to enhance an immune response to the polypeptides encoded by the nucleic acid molecules in the vectors of the disclosure. Examples of suitable adjuvants include aluminum salts such as aluminum hydroxide and/or aluminum phosphate and/or aluminum potassium phosphate; oil-emulsion compositions (or oil-in-water compositions), including squalene-water emulsions, such as MF59 (see, e.g., WO 90/14837); saponin formulations, such as, for example, QS21 and Immunostimulating Complexes (ISCOMS) (see, e.g., U.S. Pat. No. 5,057,540; WO 90/03184, WO 96/11711, WO 2004/004762, WO 2005/002620); bacterial or microbial derivatives, examples of which are monophosphoryl lipid A (MPL), 3-O-deacylated MPL (3dMPL), CpG-motif containing oligonucleotides, ADP-ribosylating bacterial toxins or mutants thereof, such as E. coli heat labile enterotoxin LT, cholera toxin CT, and the like. It is also possible to use vector-encoded adjuvant, e.g., by using heterologous nucleic acid that encodes a fusion of the oligomerization domain of C4-binding protein (C4bp) to the antigen of interest (e.g., Solabomi et al., 2008, Infect. Immun. 76:3817-23), or by using a vector encoding both the transgene of interest and a TLR-3 agonist such as heterologous dsRNA (e.g., WO 2007/100908), or the like.

In other embodiments, the compositions of the disclosure do not comprise adjuvants.

Pharmaceutical compositions may be administered to a subject, e.g., a human subject. The total dose of the vaccine active component provided to a subject during one administration can be varied as is known to the skilled practitioner, and for adenovirus is generally between 1×10⁷ viral particles (vp) and 1×10¹² vp, preferably between 1×10⁸ vp and 1×10¹¹ vp, for instance, between 3×10⁸ and 5×10¹⁰ vp, for instance, between 10⁹ and 3×10¹⁰ vp. For a DNA vaccine, total amounts of DNA per administration may, for instance, be between 1 μg and 10 mg. If a gene gun is used for administration, typically low amounts are used, e.g., 10 μg. For intramuscular injection, typically higher amounts are used, e.g., up to 5 mg.

Administration of pharmaceutical compositions can be performed using standard routes of administration. Non-limiting embodiments include parenteral administration, such as by injection, e.g., intradermal, intramuscular, etc., or subcutaneous or transcutaneous, or mucosal administration, e.g., intranasal, oral, intravaginal, rectal, and the like. In one embodiment a composition is administered by intramuscular injection, e.g., into the deltoid muscle of the arm, or vastus lateralis muscle of the thigh. In certain embodiments the vaccine is a DNA vaccine, and this can, for instance, be administered intradermally, e.g., by DNA tattooing (see, e.g., Oosterhuis et al., 2012, Curr. Top Microbiol. Immunol. 351:221-50); this route is also feasible for adenoviral vectors. In certain embodiments a composition as described herein comprises an adenoviral vector and is administered by intramuscular injection. The skilled person knows the various possibilities to administer a composition, such as a vaccine in order to induce an immune response to the antigen(s) in the vaccine.

A subject as used herein preferably is a mammal, for instance, a rodent, e.g., a mouse, or a non-human-primate, or a human. Preferably, the subject is a human subject.

The vaccines of the disclosure can be used to treat patients having one of various stages of diseases caused by HPV (in particular type 16), from incident and persistent HPV infection as such (e.g., as detected by HPV DNA testing), thus before (pre-)cancerous lesions are formed, as well as cervical intraepithelial neoplasia (CIN; also known as cervical dysplasia and cervical interstitial neoplasia, which is the potentially premalignant transformation and abnormal growth (dysplasia) of squamous cells on the surface of the cervix) up to and including cervical cancer (such as cervical squamous cell carcinoma (SCC). In addition, other HPV-induced neoplasias, such as vulvar intraepithelial neoplasia (VIN), vaginal intraepithelial neoplasia (VaIN), penile intraepithelial neoplasia (PIN), anal intraepithelial neoplasia (AIN) can be targeted as well as more advanced stages of oropharyngeal cancer (also known as head- and neck cancer), penile cancer, vaginal cancer, vulvar cancer and anal cancer. The vaccines of the disclosure thus can target a wide range of HPV induced lesions, and are likely most effective at the precancerous stages of HPV-induced disease, e.g., at the (persistent) infection and/or the neoplasia stages, where expression of E2, E6 and/or E7 is highest. It is also possible to combine the treatment using a vaccine of the disclosure with compounds that counteract or can overcome immune escape mechanisms in advanced cancer cells e.g., anti-PD1/PD-L1 antibodies, anti-CTLA-4 antibodies such as Ipilimumab, anti-LAG-3 antibodies, anti-CD25 antibodies, IDO-inhibitors, CD40 agonistic antibodies, CD137 agonistic antibodies, etc. (see, e.g., Hamid and Carvajal, 2013, Expert Opinion Biol. Ther. 13:847-861; Mellman et al., 2011, Nature Rev. 480:480-89). The therapeutic vaccination method could in principle also be used for treating external genital warts or precursors thereof in case the vaccine comprises further (sequences encoding) E6 and/or E7 of an HPV type causing external genital warts and is administered to a subject infected by such an HPV type.

As used herein, “treating” means administration of the vaccine to induce a therapeutic immune response against cells that express (epitopes of) HPV16 E6 and/or E7 in the patient, which leads to at least reduction of the level of and preferably complete removal of HPV16 infection, which results in at least slowing and preferably stopping the progress of HPV16-caused disease such as neoplasias and/or symptoms thereof. Preferably treatment with the vaccine results also in remission of more advanced stages of HPV-induced cancers. It is preferred to administer the vaccine to patients that have an established HPV infection that has been typed, so that the vaccine that encodes the polypeptide of the corresponding HPV type can be administered. In the absence of screening the vaccine can also be administered in the part of the population that is likely to be HPV infected, i.e., sexually active people. It is also possible to administer a vaccine of the disclosure to subjects that have not been infected by HPV16, e.g., for prophylactic use, possibly in combination with a vaccine against another HPV type by which the patient has been infected, or alternatively in non-infected subjects. A vaccine of the disclosure can also be administered to a subject that is subject to further treatment by other means, e.g., surgery (removal of a lesion caused by HPV16 infection), or treatment with imiquimod (comprising a TLR-7/8 agonist, see, e.g., Dayaana et al., 2010, Br. J. Cancer 102:1129-36). The effect of the treatment can be measured either by cytology or by HPV testing.

The vaccination comprises administering the vaccine of the disclosure to a subject or patient at least once. It is also possible to provide one or more booster administrations of one or more further vaccines. If a boosting vaccination is performed, typically, such a boosting vaccination will be administered to the same subject at a moment between one week and one year, preferably between two weeks and four months, after administering an immunogenic composition with the same antigen to the subject for the first time (which is in such cases referred to as “priming vaccination”). In alternative boosting regimens, it is also possible to administer different vectors, e.g., one or more adenoviruses of different serotype, or other vectors such as MVA, or DNA, or protein, to the subject as a priming or boosting vaccination. In certain embodiments, the same form of a vaccine of the disclosure is administered at least twice to the same patient in a prime-boost regimen, e.g., with the same recombinant adenovirus (such as Ad26) as described herein. In certain embodiments, a vaccine of the disclosure is administered at least twice in a prime-boost regimen, but the vector of the vaccine is different, e.g., two different serotypes of adenoviral vectors are used, e.g., priming with recombinant Ad26 and boosting with recombinant Ad35, or vice versa; or priming with DNA and boosting with an adenoviral vector, or vice versa; or priming with an adenoviral vector and boosting with an MVA vector, or vice versa. In certain embodiments, a vaccine as described herein is administered at least three times, in a prime-boost-boost regimen. Further booster administrations might be added to the regimen.

It is also an aspect of the disclosure to induce a CTL response against HPV16 in a subject, comprising administering a vaccine as described herein to the subject.

Provided is also the following non-limiting embodiments:

1) a nucleic acid molecule encoding a polypeptide comprising SEQ ID NO:1;

2) a nucleic acid molecule according to embodiment 1, wherein the polypeptide further comprises at least part of HPV E2 protein;

3) a nucleic acid molecule according to embodiment 2, wherein the at least part of the HPV E2 protein is from the E2 protein of HPV16;

4) a nucleic acid molecule according to embodiment 2, wherein the polypeptide comprises at least part of the E2 protein fused to the N-terminal side of the polypeptide with SEQ ID NO:1;

5) a nucleic acid molecule according to embodiment 2, wherein the polypeptide comprises at least part of the E2 protein fused to the C-terminal side of the polypeptide with SEQ ID NO:1;

6) a nucleic acid molecule according to embodiment 3, wherein the polypeptide comprises at least part of the E2 protein fused to the N-terminal side of the polypeptide with SEQ ID NO:1;

7) a nucleic acid molecule according to embodiment 3, wherein the polypeptide comprises at least part of the E2 protein fused to the C-terminal side of the polypeptide with SEQ ID NO:1;

8) a nucleic acid molecule according to embodiment 2, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

9) a nucleic acid molecule according to embodiment 3, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

10) a nucleic acid molecule according to embodiment 4, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

11) a nucleic acid molecule according to embodiment 5, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

12) a nucleic acid molecule according to embodiment 6, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

13) a nucleic acid molecule according to embodiment 7, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

14) a vector comprising a nucleic acid molecule according to embodiment 1, wherein a sequence encoding the polypeptide is operably linked to a promoter;

15) a vector comprising a nucleic acid molecule according to embodiment 2, wherein a sequence encoding the polypeptide is operably linked to a promoter;

16) a vector comprising a nucleic acid molecule according to embodiment 3, wherein a sequence encoding the polypeptide is operably linked to a promoter;

17) a vector comprising a nucleic acid molecule according to embodiment 4, wherein a sequence encoding the polypeptide is operably linked to a promoter;

18) a vector comprising a nucleic acid molecule according to embodiment 5, wherein a sequence encoding the polypeptide is operably linked to a promoter;

19) a vector comprising a nucleic acid molecule according to embodiment 6, wherein a sequence encoding the polypeptide is operably linked to a promoter;

20) a vector comprising a nucleic acid molecule according to embodiment 7, wherein a sequence encoding the polypeptide is operably linked to a promoter;

21) a vector comprising a nucleic acid molecule according to embodiment 8, wherein a sequence encoding the polypeptide is operably linked to a promoter;

22) a vector comprising a nucleic acid molecule according to embodiment 9, wherein a sequence encoding the polypeptide is operably linked to a promoter;

23) a vector comprising a nucleic acid molecule according to embodiment 10, wherein a sequence encoding the polypeptide is operably linked to a promoter;

24) a vector comprising a nucleic acid molecule according to embodiment 11, wherein a sequence encoding the polypeptide is operably linked to a promoter;

25) a vector comprising a nucleic acid molecule according to embodiment 12, wherein a sequence encoding the polypeptide is operably linked to a promoter;

26) a vector comprising a nucleic acid molecule according to embodiment 13, wherein a sequence encoding the polypeptide is operably linked to a promoter;

27) a vector according to embodiment 14, wherein the vector is an adenovirus;

28) a vector according to embodiment 15, wherein the vector is an adenovirus;

29) a vector according to embodiment 16, wherein the vector is an adenovirus;

30) a vector according to embodiment 17, wherein the vector is an adenovirus;

31) a vector according to embodiment 18, wherein the vector is an adenovirus;

32) a vector according to embodiment 19, wherein the vector is an adenovirus;

33) a vector according to embodiment 20, wherein the vector is an adenovirus;

34) a vector according to embodiment 21, wherein the vector is an adenovirus;

35) a vector according to embodiment 22, wherein the vector is an adenovirus;

36) a vector according to embodiment 23, wherein the vector is an adenovirus;

37) a vector according to embodiment 24, wherein the vector is an adenovirus;

38) a vector according to embodiment 25, wherein the vector is an adenovirus;

39) a vector according to embodiment 26, wherein the vector is an adenovirus;

40) a vector according to embodiment 27, wherein the adenovirus is a human adenovirus of serotype 26;

41) a vector according to embodiment 28, wherein the adenovirus is a human adenovirus of serotype 26;

42) a vector according to embodiment 29, wherein the adenovirus is a human adenovirus of serotype 26;

43) a vector according to embodiment 30, wherein the adenovirus is a human adenovirus of serotype 26;

44) a vector according to embodiment 31, wherein the adenovirus is a human adenovirus of serotype 26;

45) a vector according to embodiment 32, wherein the adenovirus is a human adenovirus of serotype 26;

46) a vector according to embodiment 33, wherein the adenovirus is a human adenovirus of serotype 26;

47) a vector according to embodiment 34, wherein the adenovirus is a human adenovirus of serotype 26;

48) a vector according to embodiment 35, wherein the adenovirus is a human adenovirus of serotype 26;

49) a vector according to embodiment 36, wherein the adenovirus is a human adenovirus of serotype 26;

50) a vector according to embodiment 37, wherein the adenovirus is a human adenovirus of serotype 26;

51) a vector according to embodiment 38, wherein the adenovirus is a human adenovirus of serotype 26;

52) a vector according to embodiment 39, wherein the adenovirus is a human adenovirus of serotype 26;

53) a vector according to embodiment 28, wherein the adenovirus is a human adenovirus of serotype 35;

54) a vector according to embodiment 29, wherein the adenovirus is a human adenovirus of serotype 35;

55) a vector according to embodiment 30, wherein the adenovirus is a human adenovirus of serotype 35;

56) a vector according to embodiment 31, wherein the adenovirus is a human adenovirus of serotype 35;

57) a vector according to embodiment 32, wherein the adenovirus is a human adenovirus of serotype 35;

58) a vector according to embodiment 33, wherein the adenovirus is a human adenovirus of serotype 35;

59) a vector according to embodiment 34, wherein the adenovirus is a human adenovirus of serotype 35;

60) a vector according to embodiment 35, wherein the adenovirus is a human adenovirus of serotype 35;

61) a vector according to embodiment 36, wherein the adenovirus is a human adenovirus of serotype 35;

62) a vector according to embodiment 37, wherein the adenovirus is a human adenovirus of serotype 35;

63) a vector according to embodiment 38, wherein the adenovirus is a human adenovirus of serotype 35;

64) a vector according to embodiment 39, wherein the adenovirus is a human adenovirus of serotype 35;

65) a vaccine composition comprising a vector according to embodiment 14, and a pharmaceutically acceptable excipient;

66) a vaccine composition comprising a vector according to embodiment 15, and a pharmaceutically acceptable excipient;

67) a vaccine composition comprising a vector according to embodiment 16, and a pharmaceutically acceptable excipient;

68) a vaccine composition comprising a vector according to embodiment 17, and a pharmaceutically acceptable excipient;

69) a vaccine composition comprising a vector according to embodiment 18, and a pharmaceutically acceptable excipient;

70) a vaccine composition comprising a vector according to embodiment 19, and a pharmaceutically acceptable excipient;

71) a vaccine composition comprising a vector according to embodiment 20, and a pharmaceutically acceptable excipient;

72) a vaccine composition comprising a vector according to embodiment 21, and a pharmaceutically acceptable excipient;

73) a vaccine composition comprising a vector according to embodiment 22, and a pharmaceutically acceptable excipient;

74) a vaccine composition comprising a vector according to embodiment 23, and a pharmaceutically acceptable excipient;

75) a vaccine composition comprising a vector according to embodiment 24, and a pharmaceutically acceptable excipient;

76) a vaccine composition comprising a vector according to embodiment 25, and a pharmaceutically acceptable excipient;

77) a vaccine composition comprising a vector according to embodiment 26, and a pharmaceutically acceptable excipient;

78) a vaccine composition comprising a vector according to embodiment 27, and a pharmaceutically acceptable excipient;

79) a vaccine composition comprising a vector according to embodiment 28, and a pharmaceutically acceptable excipient;

80) a vaccine composition comprising a vector according to embodiment 29, and a pharmaceutically acceptable excipient;

81) a vaccine composition comprising a vector according to embodiment 30, and a pharmaceutically acceptable excipient;

82) a vaccine composition comprising a vector according to embodiment 31, and a pharmaceutically acceptable excipient;

83) a vaccine composition comprising a vector according to embodiment 32, and a pharmaceutically acceptable excipient;

84) a vaccine composition comprising a vector according to embodiment 33, and a pharmaceutically acceptable excipient;

85) a vaccine composition comprising a vector according to embodiment 34, and a pharmaceutically acceptable excipient;

86) a vaccine composition comprising a vector according to embodiment 35, and a pharmaceutically acceptable excipient;

87) a vaccine composition comprising a vector according to embodiment 36, and a pharmaceutically acceptable excipient;

88) a vaccine composition comprising a vector according to embodiment 37, and a pharmaceutically acceptable excipient;

89) a vaccine composition comprising a vector according to embodiment 38, and a pharmaceutically acceptable excipient;

90) a vaccine composition comprising a vector according to embodiment 39, and a pharmaceutically acceptable excipient;

91) a vaccine composition comprising a vector according to embodiment 40, and a pharmaceutically acceptable excipient;

92) a vaccine composition comprising a vector according to embodiment 41, and a pharmaceutically acceptable excipient;

93) a vaccine composition comprising a vector according to embodiment 42, and a pharmaceutically acceptable excipient;

94) a vaccine composition comprising a vector according to embodiment 43, and a pharmaceutically acceptable excipient;

95) a vaccine composition comprising a vector according to embodiment 44, and a pharmaceutically acceptable excipient;

96) a vaccine composition comprising a vector according to embodiment 45, and a pharmaceutically acceptable excipient;

97) a vaccine composition comprising a vector according to embodiment 46, and a pharmaceutically acceptable excipient;

98) a vaccine composition comprising a vector according to embodiment 47, and a pharmaceutically acceptable excipient;

99) a vaccine composition comprising a vector according to embodiment 48, and a pharmaceutically acceptable excipient;

100) a vaccine composition comprising a vector according to embodiment 49, and a pharmaceutically acceptable excipient;

101) a vaccine composition comprising a vector according to embodiment 50, and a pharmaceutically acceptable excipient;

102) a vaccine composition comprising a vector according to embodiment 51, and a pharmaceutically acceptable excipient;

103) a vaccine composition comprising a vector according to embodiment 52, and a pharmaceutically acceptable excipient;

104) a vaccine composition comprising a vector according to embodiment 53, and a pharmaceutically acceptable excipient;

105) a vaccine composition comprising a vector according to embodiment 54, and a pharmaceutically acceptable excipient;

106) a vaccine composition comprising a vector according to embodiment 55, and a pharmaceutically acceptable excipient;

107) a vaccine composition comprising a vector according to embodiment 56, and a pharmaceutically acceptable excipient;

108) a vaccine composition comprising a vector according to embodiment 57, and a pharmaceutically acceptable excipient;

109) a vaccine composition comprising a vector according to embodiment 58, and a pharmaceutically acceptable excipient;

110) a vaccine composition comprising a vector according to embodiment 59, and a pharmaceutically acceptable excipient;

111) a vaccine composition comprising a vector according to embodiment 60, and a pharmaceutically acceptable excipient;

112) a vaccine composition comprising a vector according to embodiment 61, and a pharmaceutically acceptable excipient;

113) a vaccine composition comprising a vector according to embodiment 62, and a pharmaceutically acceptable excipient;

114) a vaccine composition comprising a vector according to embodiment 63, and a pharmaceutically acceptable excipient;

115) a vaccine composition comprising a vector according to embodiment 64, and a pharmaceutically acceptable excipient;

116) a method for inducing an immune response against HPV in a subject, comprising administering to the subject a vaccine composition according to any one of embodiments 65-115;

117) a method for treating persistent HPV (type 16) infection, comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from persistent HPV infection;

118) a method for treating vulvar intraepithelial neoplasia (VIN) (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from VIN;

119) a method for treating vulvar cancer (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from vulvar cancer;

120) a method for treating cervical intraepithelial neoplasia (CIN) (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from CIN;

121) a method for treating cervical cancer (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from cervical cancer;

122) a method for treating oropharyngeal cancer (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from oropharyngeal cancer;

123) a method for treating penile intraepithelial neoplasia (PIN) (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from PIN;

124) a method for treating penile cancer (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from penile cancer;

125) a method for treating vaginal intraepithelial neoplasia (VaIN) (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from VaIN;

126) a method for treating vaginal cancer (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from vaginal cancer;

127) a method for treating anal intraepithelial neoplasia (AIN) (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from AIN;

128) a method for treating anal cancer (with underlying HPV type 16 infection), the method comprising administering a vaccine according to any one of embodiments 65-115 to a subject that suffers from anal cancer;

129) a polypeptide comprising SEQ ID NO:1;

130) a polypeptide according to embodiment 129, wherein the polypeptide further comprises at least part of HPV E2 protein;

131) a polypeptide according to embodiment 130, wherein the at least part of the HPV E2 protein is from the E2 protein of HPV16;

132) a polypeptide according to embodiment 130, wherein at least part of the E2 protein is fused to the N-terminal side of the polypeptide with SEQ ID NO:1;

133) a polypeptide according to embodiment 130, wherein at least part of the E2 protein is fused to the C-terminal side of the polypeptide with SEQ ID NO:1;

134) a polypeptide according to embodiment 131, wherein at least part of the E2 protein is fused to the N-terminal side of the polypeptide with SEQ ID NO:1;

135) a polypeptide according to embodiment 131, wherein at least part of the E2 protein is fused to the C-terminal side of the polypeptide with SEQ ID NO:1;

136) a polypeptide according to embodiment 130, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

137) a polypeptide according to embodiment 131, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

138) a polypeptide according to embodiment 132, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

139) a polypeptide according to embodiment 133, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

140) a polypeptide according to embodiment 134, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

141) a polypeptide according to embodiment 135, wherein the at least part of the E2 protein comprises a variant of the E2 protein with a mutation that abrogates DNA binding of E2;

142) a nucleic acid molecule according to embodiment 3, encoding a polypeptide according to SEQ ID NO:3;

143) a nucleic acid molecule according to embodiment 3, encoding a polypeptide according to SEQ ID NO:5;

144) a vector encoding a nucleic acid molecule according to embodiment 142, wherein a sequence encoding the polypeptide is operably linked to a promoter;

145) a vector encoding a nucleic acid molecule according to embodiment 143, wherein a sequence encoding the polypeptide is operably linked to a promoter;

146) a vector according to embodiment 144, wherein the vector is an adenovirus;

147) a vector according to embodiment 145, wherein the vector is an adenovirus;

148) a vector according to embodiment 146, wherein the adenovirus is a human adenovirus of serotype 26;

149) a vector according to embodiment 147, wherein the adenovirus is a human adenovirus of serotype 26;

150) a vector according to embodiment 146, wherein the adenovirus is a human adenovirus of serotype 35;

151) a vector according to embodiment 147, wherein the adenovirus is a human adenovirus of serotype 35;

152) a vaccine composition comprising a vector according to embodiment 144, and a pharmaceutically acceptable excipient;

153) a vaccine composition comprising a vector according to embodiment 145, and a pharmaceutically acceptable excipient;

154) a vaccine composition comprising a vector according to embodiment 146, and a pharmaceutically acceptable excipient;

155) a vaccine composition comprising a vector according to embodiment 147, and a pharmaceutically acceptable excipient;

156) a vaccine composition comprising a vector according to embodiment 148, and a pharmaceutically acceptable excipient;

157) a vaccine composition comprising a vector according to embodiment 149, and a pharmaceutically acceptable excipient;

158) a vaccine composition comprising a vector according to embodiment 150, and a pharmaceutically acceptable excipient;

159) a vaccine composition comprising a vector according to embodiment 151, and a pharmaceutically acceptable excipient;

160) a method for inducing an immune response against HPV in a subject, the method comprising administering to the subject a vaccine composition according to any one of embodiments 152-159;

161) a method for treating vulvar intraepithelial neoplasia (VIN), the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from VIN;

162) a method for treating vulvar cancer, the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from vulvar cancer;

163) a method for treating cervical intraepithelial neoplasia (CIN), the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from CIN;

164) a method for treating cervical cancer, the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from cervical cancer;

165) a method for treating oropharyngeal cancer, the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from oropharyngeal cancer;

166) a method for treating penile intraepithelial neoplasia (PIN), the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from PIN;

167) a method for treating penile cancer, the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from penile cancer;

168) a method for treating vaginal intraepithelial neoplasia (VaIN), the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from VaIN;

169) a method for treating vaginal cancer, the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from vaginal cancer;

170) a method for treating anal intraepithelial neoplasia (AIN), the method the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from AIN;

171) a method for treating anal cancer, the method comprising administering a vaccine according to any one of embodiments 152-159 to a subject that suffers from anal cancer.

The practice of this disclosure will employ, unless otherwise indicated, conventional techniques of immunology, molecular biology, microbiology, cell biology, and recombinant DNA, which are within the skill of the art. See, e.g., Sambrook, Fritsch and Maniatis, Molecular Cloning: A Laboratory Manual, 2^(nd) edition, 1989; Current Protocols in Molecular Biology, F. M. Ausubel et al., eds., 1987; the series Methods in Enzymology (Academic Press, Inc.); PCR2: A Practical Approach, M. J. MacPherson, B. D. Hams, G. R. Taylor, eds., 1995; Antibodies: A Laboratory Manual, Harlow and Lane, eds., 1988.

The disclosure is further described by the following illustrative examples. The examples are not to limit the disclosure in any way.

EXAMPLES Example 1 Construction of a Designer Polypeptide Comprising Essentially all HPV16 E6 and E7 CTL Epitopes

We designed a novel, non-tumorigenic polypeptide (and nucleic acid molecule encoding such) that contains essentially all CTL epitopes of HPV16 E6 and E7 proteins, and has a minimum number of anticipated/predicted strong neo-epitopes (neo-epitopes meaning epitopes not present in the wild type HPV16 E6 and E7 proteins). A polypeptide (also sometimes referred to as “E6E7SH” herein) comprises a sequence as provided in SEQ ID NO:1. A codon-optimized nucleic acid molecule encoding this polypeptide is provided in SEQ ID NO:2.

The molecules are single molecules, which provides manufacturing advantages over strategies where multiple molecules are used. In addition, the polypeptide of the disclosure comprises essentially all putative CTL epitopes that are present in wild-type E6 and E7 of HPV16, and at the same time have a minimum number of anticipated/predicted strong neo-epitopes that could potentially be immunodominant and thus divert the immune response from relevant wild-type CTL epitopes. Thus the constructs of the disclosure are immunologically more favorable than molecules described by others that either lack possible CTL epitopes and/or that contain more or stronger neo-epitopes.

For instance, the construct of SEQ ID NO:1 contains only one neo-epitope with a length of nine amino acids with a predicted binding affinity <50 nM for the 20 most common HLA-A, 20 most common HLA-B and 20 most common HLA-C alleles (HLA-A*01:01, HLA-A*02:01, HLA-A*02:03, HLA-A*02:06, HLA-A*02:07, HLA-A*03:01, HLA-A*11:01, HLA-A*23:01, HLA-A*24:02, HLA-A*26:01, HLA-A*29:02, HLA-A*30:01, HLA-A*30:02, HLA-A*31:01, HLA-A*32:01, HLA-A*33:01, HLA-A*33:03, HLA-A*34:01, HLA-A*68:01, HLA-A*68:02, HLA-B*07:02, HLA-B*07:04, HLA-B*08:01, HLA-B*13:01, HLA-B*15:01, HLA-B*18:01, HLA-B*35:01, HLA-B*37:01, HLA-B*39:01, HLA-B*40:01, HLA-B*40:02, HLA-B*40:06, HLA-B*44:02, HLA-B*44:03, HL-B*46:01, HLA-B*48:01, HLA-B*51:01, HLA-B*52:01, HLA-B*53:01, HLA-B*58:01, HLA-C*07:02, HLA-C*04:01, HLA-C*03:04, HLA-C*01:02, HLA-C*07:01, HLA-C*06:02, HLA-C*03:03, HLA-C*08:01, HLA-C*15:02, HLA-C*12:02, HLA-C*02:02, HLA-C*05:01, HLA-C*14:02, HLA-C*03:02, HLA-C*16:01, HLA-C*08:02, HLA-C*12:03, HLA-C*04:03, HLA-C*17:01, HLA-C*14:03), as determined using the ANN (Lundegaard et al., 2008, Nucl. Acids Res. 36:W509-12) and SMM method (Peters et al., 2003, Bioinformatics 19:1765-72) for HLA-A and HLA-B and the NetMHCpan method (Hoof et al., 2009, Immunogenetics 61:1-13) for HLA-C of the prediction tool for “Peptide binding to MHC class I molecules” at the IEDB website (at tools.immuneepitope.org/analyze/html/mhc_binding.html, version 2009-09-01B).

As a non-limiting example, using the SMM prediction tool at the IEDB website, the shuffled E6 and E7 sequences as described by Oosterhuis et al., 2011, Int. J. Cancer 129:397-406, and Öhlschlager et al., 2006, Vaccine 24:2880-93 contain each nine potential strong unique neo-epitopes (ANN or SMM IC50<50 nM) for the 20 most HLA-A and -B, in the core part. This even excludes the appendices used in that approach (in which appendices will further contribute to additional neo-epitopes, and may miss out on more native MHC II epitopes due to the limited length of the “overlap”). Indeed, a reportedly improved molecule containing a variant with shuffled E6 and E7 proteins that was described in WO 2013/083287, contains 22 unique neo-epitopes with a length of nine amino acids with a predicted IC50<50 nM (ANN, SMM or NetMHCPan) for the 20 most common HLA-A, 20 most common HLA-B and 20 most common HLA-C alleles.

Hence, the designer molecules hereof clearly are favorable in having much lower number of predicted neo-epitopes compared to other published approaches where E6 and E7 where shuffled to remove functionality.

Nucleic acid molecule encoding the thus designed HPV16 E6E7SH molecule (i.e., a polypeptide comprising SEQ ID NO:1) was synthesized, the polynucleotide comprising SEQ ID NO:2, and flanked by a HindIII site and a Kozak sequence on the 5′ end and an Xbal site on the 3′ site (custom synthesis and standard molecular cloning at Invitrogen Life technologies, Germany).

The synthesized fragments were cloned using HindIII and XbaI into a standard expression vector, pCDNA2004.Neo, harboring both a bacterial resistance marker (Ampicillin) and a mammalian resistance marker (Neomycin), to obtain plasmid vectors encoding a molecule of the disclosure, e.g., for (transient) transfection based experiments.

These molecules could be used as such, but also as the basis for further molecules that contain additional features. As non-limiting examples, some further variants were prepared as described below.

The HPV16 E6E7SH fusion protein sequence can be combined with sequences of other HPV16 early proteins to target individuals with persistent infection and to broaden the immune repertoire in an immunized individual. Immune responses against E2 have been suggested to play an important role in the clearance of HPV16 infections (de Jong et al., 2002, Cancer Res. 62:472-479). Fusion of E2 to E6E7SH will give a vaccine component that harbors antigens against the stages of HPV-related cancer from persistent infection to invasive cancer or recurrent/refractory disease after LEEP surgery. Therefore, as a non-limiting example of such embodiments, we prepared a sequence coding for a fusion protein of E6E7SH with E2 at its N-terminus. In the E2 sequence modifications can be made to abrogate DNA binding activity that might affect gene expression in cells expressing the fusion protein. We mutated Glycine at position 293, Lysine at position 299 and Cysteine at position 300 of the wt HPV16 E2 protein into respectively Valine, Methionine and Arginine. Each of these mutations on its own already completely abrogates the binding of E2 to DNA sequences that harbor E2 binding domains (Prakash et al., 1992, Genes Dev. 6:105-16).

The resulting polypeptide is referred to as HPV16 E2E6E7SH and comprises SEQ ID NO:3. A codon-optimized sequence encoding this polypeptide was prepared and is provided in SEQ ID NO:4.

We also constructed a variant wherein the same E2 mutant protein was fused to the C-terminus of the HPV16 E6E7SH fusion polypeptide, giving rise to a polypeptide referred to as HPV16 E6E7E2SH, which comprises SEQ ID NO:5. The sequence encoding this construct is provided as SEQ ID NO:6.

For control purposes, we also constructed sequences encoding a polypeptide that contains the wild-type sequences for full-length HPV16 E6 and E7 as a fusion protein (E6 from aa 1 to 158 directly fused to E7 from aa 1 to 98, named herein E6E7wt).

We also tested the effect of adding leader sequences to the polypeptide. As a non-limiting example, a sequence encoding an IgE leader sequence (see, e.g., U.S. Pat. No. 6,733,994) [the sequence of the leader peptide is provided in SEQ ID NO:7] was fused at the N-terminus of some of the constructs, e.g., in the E6E7wt construct, which rendered LSE6E7wt, and in the E2E6E7SH construct, which rendered LSE2E6E7SH. The effect thereof was significantly (p<0.05) enhanced immunogenicity in comparison to the same antigen without the LS sequence as measured by E7-tetramer analysis in immunized mice (as can, for instance, be seen in FIGS. 9A-9C).

The sequences that encode the E6E7SH polypeptides hereof, with or without E2, can, for instance, be expressed from DNA constructs, from RNA or from viral vectors. FIG. 1 demonstrates expression in HEK-293T cells upon transient transfection with DNA vectors expressing the transgenes as described above. After transfection, cells were harvested and cell extracts were analyzed by SDS-PAGE and western blotting with an antibody against HPV16 E7. This experiment demonstrates expression of the expected fusion proteins of appropriate size upon transfection of the expression vectors.

Adenoviral vectors can be used to express the E6E7, either with or without E2, and with or without additional sequences to augment the immunogenicity of the encoded fusion protein.

The genes, coding for HPV16 E6E7 wt control or HPV designer sequences described above were gene optimized for human expression and synthesized, by GENEART®. A Kozak sequence (5′ GCCACC 3′) was included directly in front of the ATG start codon, and two stop codons (5′ TGA TAA 3′) were added at the end of the respective coding sequence. The genes were inserted in the pAdApt35BSU plasmid and in the pAdApt26 plasmid (Havenga et al., 2006, J. Gen. Virol. 87:2135-43) via HindIII and XbaI sites.

All adenoviruses were generated in PER.C6® cells by single homologous recombination and produced as previously described (for rAd35: Havenga et al., 2006, J. Gen. Virol. 87:2135-43; for rAd26: Abbink et al., 2007, J. Virol. 81:4654-63). PER.C6® cells (Fallaux et al., 1998, Hum. Gene Ther. 9:1909-17) were maintained in Dulbecco's modified Eagle's medium (DMEM) with 10% fetal bovine serum (FBS), supplemented with 10 mM MgCl2.

Briefly, PER.C6® cells were transfected with Ad vector plasmids, using Lipofectamine according to the instructions provided by the manufacturer (Life Technologies). Cells were harvested one day after full cytopathic effect (CPE) was reached, freeze-thawed, centrifuged for 5 min at 3,000 rpm, and stored at −20° C. The viruses were plaque purified and amplified in PER.C6® cells cultured in a single well of a multiwell 24-tissue culture plate. Further amplification was carried out in PER.C6® cells cultured in a T25 tissue culture flask and subsequently in a T175 tissue culture flask. Of the crude lysate prepared from the cells obtained after the T175 flask, 3 to 5 ml was used to inoculate 24×T1000 five-layer tissue culture flasks containing 70% confluent layers of PER.C6® cells. The virus was purified using a two-step CsCl purification method. Finally, the virus was stored in aliquots at −85° C.

Ad35.HPV16-E6E7wt, and Ad35.HPV16-E6E7SH are recombinant adenovirus serotype 35 (Ad35) vectors comprising the codon-optimized nucleotide sequences for the expression of, respectively, a fusion protein of the wild type HPV16 E6 and E7 proteins (E6E7wt), and a designer fusion protein variant as described above (E6E7SH, having the amino acid sequence provided in SEQ ID NO:1). The combined E6 and E7 sequences were placed under the control of a CMV promoter in the E1 region of the E1, E3 deleted adenovirus genome. Ad26.HPV16-E6E7wt, and Ad26.HPV16-E6E7SH are the equivalent vectors based on recombinant adenovirus serotype 26.

Similarly, Ad26 and Ad35-based recombinant adenoviral vectors were produced that encode the HPV16 E2E6E7SH (SEQ ID NO:3) variant. Likewise, Ad26 and Ad35 encoding the HPV16 E6E7E2SH (SEQ ID NO:5) variant were produced. Also, an Ad35 vector encoding the E2E6E7SH fusion protein with an IgE leader sequence at the N-terminus was produced, named Ad35.HPV16-LSE2E6E7SH. Also a control adenovirus with the E6E7wt fused to the IgE leader sequence at the N-terminus was produced.

The recombinant adenoviruses were produced on PER.C6® cells and purified by centrifugation on cesium chloride gradients.

Further examples of constructs of the disclosure that were coupled to repressor systems are provided in a later example below.

Example 2 Lack of Transforming Activity of the Designer Constructs

Wild-type HPV16 E6 and E7 proteins have tumorigenic potential, which is apparent as transforming activity in certain assays, such as colony formation in a soft-agar assay (Massimi and Banks, 2005, Methods Mol. Med. 119:381-395). The E6E7SH polypeptide as described in Example 1 comprises the fragments of the E6 and E7 proteins in a re-ordered fashion. This is expected to remove the tumorigenic potential, as can be measured, for instance, by a significantly reduced transforming activity as compared to either of wt E6 and E7 proteins in such assays.

Others reported that gene-shuffled variants of HPV16 E6 and E7 have indeed lost their oncogenic potential (Öhlschlager et al., 2006, Vaccine 24:2880-93; Henken et al., 2012, Vaccine 30:4259-66), demonstrating that gene shuffling destroys the wild-type functions of E6 and E7 proteins.

To assess the loss of tumorigenic properties, we assessed the ability of our E6E7SH constructs to confer the ability to grow in soft agar upon NIH 3T3 cells (as described by, e.g., Massimi and Banks, 2005, Methods Mol. Med. 119:381-395). Transfection of NIH3T3 cells with a plasmid expressing the wild type HPV16 E7 resulted consistently in colony formation. In these assays, expression of wild type HPV16 E6 alone did not cause colony formation above background. This is in line with published observations that E7wt is much more efficient than E6wt in this assay (Sedman et al., 1991, J. Virol. 65:4860-66). Transfection with our E6E7SH construct did not lead to growth of colonies of cells in soft agar (FIGS. 2A-2C) in four independent experiments, demonstrating that nucleic acids encoding a polypeptide of the disclosure, E6E7SH, have lost the transforming capacity that is associated with E7.

The tumorigenic potential of E6 and E7 is associated with their ability to reduce the levels of the cellular proteins p53 and pRb respectively. p53 and pRb degradation assays were performed to demonstrate that nucleic acid molecule encoding a polypeptide of the disclosure, E6E7SH, construct does not have the biological activity associated with the wild-type E6 and E7 at the molecular level. In short, HPV16 E6wt and our E6E7SH construct were expressed in NCI-H1299 cells that lack endogenous p53 for the p53 degradation assay. For the pRb degradation assay HPV16 E7wt and the E6E7SH construct were expressed in pRb null Saos-2 cells. As can be seen in FIGS. 3A-3D, co-expression of p53 with E6wt, but not with E6E7SH, leads to reduced p53 levels (FIGS. 3A and 3B). Likewise, FIGS. 3C and 3D show that co-expression of pRb with E7wt, but not with E6E7SH, leads to reduced pRB levels. These data demonstrate that nucleic acid molecule encoding a polypeptide of the disclosure has no ability to form colonies in soft agar and does not contain main biological activities of the wild-type E6 and E7 polypeptides, namely the inactivation of p53 and pRb respectively.

To further demonstrate the safety of nucleic acid constructs encoding polypeptide of the disclosure, we made use of primary human foreskin keratinocytes that are the natural target cells for HPV mediated transformation. Immortalization of primary human keratinocytes requires the action of both E6 and E7 wild-type (Munger et al., 1989, J. Virol. 63:4417-21). This assay is probably the physiologically most relevant in vitro assay to demonstrate the safety of our constructs (Massimi and Banks, 2005, Methods Mol. Med. 119:381-395). Cells transduced with lentiviruses expressing wild type E6 and E7 from HPV16 (E6E7wt) induce immortalization in primary keratinocytes as indicated by the extension of their lifespan as compared to non-transduced control cells (FIG. 4) and activation of hTERT, the catalytic subunit of telomerase (data not shown). Expression of the polypeptide of the disclosure (E6E7SH) is not able to extend the lifespan compared to GFP-transduced or non-transduced keratinocytes. A similar result was obtained in two additional independent donors (data not shown). Taken together these data demonstrate that our constructs have lost the ability to induce immortalization in primary human keratinocytes that are considered a highly physiological model.

Another construct wherein fragments of HPV16 E6 and E7 were recombined in another order was also incapable of immortalization of primary human foreskin keratinocytes. However, an expanded life span up to approximately 120-150 days was observed for that construct. This indicates some unpredictability in this field, and demonstrates the superiority of the designer molecules as described herein in this safety-related aspect.

All together the experiments in this example provide strong evidence of the lack of transforming activity of nucleic acids encoding polypeptides as described herein, and thus a strongly improved safety over HPV16 E6 and E7 wt constructs.

Example 3 Immune Responses to the E6E7SH Designer Constructs

We have prepared DNA vectors and adenoviral vectors, as described in Example 1.

We used the CB6F1 mouse strain for measuring immune responses, based on initial experiments where mice where immunized with DNA plasmids encoding wild type E2, or E6 or E7, and immunization with HPV16 E2, E6 and E7 antigens induced a broader cellular immune response in CB6F1 than in C57BL/6 mice or Balb/c mice. In a separate experiment mice were immunized with DNA vectors encoding molecules of the disclosure and cellular immune responses were measured. HPV16 E7-specific immune responses could be measured in mice immunized with DNA plasmids expressing E6E7SH (FIGS. 5A and 5B).

The following data shown in this example are from mouse experiments that were carried out with adenoviral vectors.

To evaluate the vaccine induced immunogenicity, CB6F1 mice were immunized with adenovectors (Ad35) expressing E6E7wt, LSE6E7wt, E6E7SH or adenovectors not encoding a transgene (Empty). Two doses were tested for administration to the mice: 5*10⁹ viral particles (vp) and 1*10¹⁰ vp. Two and eight weeks after immunization the mice were sacrificed and isolated splenocytes were stimulated overnight with an HPV16 E7 15 mer peptide pool. E7-specific responses at two weeks and at eight weeks were analyzed by IFNγ ELISPOT. The data are presented in FIGS. 6A-6C.

This shows that immunization of mice with Ad35.HPV16-E6E7SH induces E7-specific immune responses as measured by ELISPOT analysis. In addition, the results in FIGS. 6A-6C demonstrate the possibility to enhance the immune response against an adenoviral expressed transgene by adding an N-terminal leader sequence to the transgene.

Next the effect of adding E2 to the E6E7SH polypeptide with respect to immunogenicity was tested. The Ad35 vectors encoded polypeptides that had E2 either fused to the N-terminus (E2E6E7SH) or to the C-terminus (E6E7E2SH). CB6F1 mice were immunized with a dose of 1×10¹⁰ vp. FIGS. 7A and 7B (E7-tetramer staining) and FIG. 8C (IFNγ ELISPOT) show the immune responses against E7, which for the designer constructs including E2 tends to be higher in comparison to the construct without E2, although the differences were not statistically significant. The response against E2 was higher for adenoviral vectors encoding only E2 compared to the response for adenoviral vectors that had E2 fused to the E6E7SH designer polypeptide (FIG. 8B), with differences being significant for both E2 vs E2E6E7SH and E2 vs E6E7E2SH (p-value: <0.05).

It is concluded that the designer constructs that further include E2 can still provide an immune response against E7, and in addition also provide an immune response against E2, thus increasing the breadth of the immune response over the constructs that do not include E2.

Addition of a leader sequence was shown to result in higher E7-specific responses when fused to the N-terminus of the fusion protein of wild type E6 and E7 (FIG. 6C). Similarly, the effect of the leader sequence on immunogenicity of the E2E6E7SH fusion protein was determined. Therefore, Ad35 vectors encoding the designer polypeptide, with or without N-terminal E2 and an Ad35 vector encoding LSE2E6E7SH were used for immunization of mice and blood samples were taken at two-week intervals to measure E7-specific immune responses (FIGS. 9A-9C). As shown in FIGS. 7A, 7B, and 8A-8C, the presence of E2 at either N- or C-terminally fused to E6E7SH tended to increase the immune responses. Addition of the IgE leader sequence further increased the E7-specific response (FIG. 9B). Over time sustained immune responses were observed for all three adenoviral vectors that encoded designer molecules as described herein, and the highest response after the immunization corresponded with the highest responses over the duration of the experiment.

It is concluded that the responses that are induced by the designer construct that further includes N-terminal E2 can be increased by addition of specific sequences, e.g., the IgE leader sequence, that target the encoded protein to specific cellular compartments.

The cellular immune response against the peptide of the disclosure can be induced with different types of adenoviral vectors. In the previous experiment we used Ad35 vectors, while in the experiment of FIGS. 10A and 10B, mice were immunized with an Ad26 adenoviral vector expressing E2E6E7SH. The data show that also immunization with an Ad26-based vaccine induced E7-specific T-cells. In addition, the results demonstrate that a second immunization with an Ad35 adenoviral vector expressing E2E6E7SH further boosted the cellular immune responses (FIGS. 10A and 10B).

Example 4 Immunogenicity of Designer Constructs in Rhesus Macaques.

To evaluate the ability of the adenoviral vectors expressing the designer sequence of the disclosure to induce immune responses in non-human primates, rhesus macaques were immunized by intramuscular injection with adenovectors (Ad26) expressing E2E6E7SH or adenovectors not encoding a transgene (Empty), with a dose of 1*10¹¹ vp. Eight weeks after the immunization the immune responses were boosted by immunization with Ad26 vectors expressing the same antigen. At week 16 the animals received one more injection with the Ad35 vectors expressing the same antigen. Blood samples were taken at several time points and isolated white blood cells were stimulated overnight with a peptide pools corresponding to HPV16 E2, E6 or E7. Specific responses were measured by IFNγ ELISPOT. The data are presented in FIGS. 11A and 11B. In addition at week 10 and week 18 post-prime immunization, the cellular immune response specific to peptides spanning the novel junctions in the disclosure was evaluated. The induction of IFNγ response was in all animals below the limit of detection of <50 SFU per 1*10⁶ PBMC (data not shown).

The data show that immunization of non-human primates with Ad26.HPV16-E2E6E7SH resulted in cellular immune responses against all three HPV16 proteins that are present in the encoded transgene, but not against the novel junctions. Responses could be boosted by the additional immunization with Ad26.HPV16-E2E6E7SH and additional boost at week 16 with the corresponding Ad35 vector further increased the HPV16 E2, E6 and E7-specific immune responses.

A late booster administration at week 72 with Ad26.HPV16-E2E6E7SH again resulted in an increase of the HPV16 cellular immune response, which after a few weeks was declined (not shown).

In a separate experiment (not shown), Rhesus macaques were immunized by intravaginal administration with a combination of two adenoviral vectors, one expressing HPV16 E6E7SH and the other the HPV16 L1 protein. Low but measurable cellular responses were measured in peripheral mononuclear blood cells against both E6 and E7. In these experiments, strong cellular immune responses against L1 were detected.

Example 5 Therapeutic Efficacy in a Mouse Tumor Model

The polypeptide of the disclosure is capable of inducing HPV16-specific cellular immune response in animals, which can exert a therapeutic effect on cells expressing HPV16 E6 and/or E7. Therapeutic immunization, i.e., immunization after tumor growth has started, can be used to demonstrate efficacy of a therapeutic HPV vaccine candidate. The therapeutic effect of Ad26 and Ad35 vectors was tested in mice that were injected with TC-1 cells (mouse cells expressing HPV16 E6 and E7) (Lin et al., 1996, Cancer Res. 56:21-6). TC-1 cells will form solid tumor within a few days to weeks after sub-cutaneous injection in mice. Without vaccine the tumors grew rapidly and reach a pre-determined size of 1000 mm³ within 30 days (FIGS. 12D and 12E). Upon reaching this size the mice are sacrificed for ethical reasons.

With a prime-boost immunization scheme with SLPs (used as a positive control; Kenter et al., 2009, N. Engl. J. Med. 361:1838-47; Zwaveling et al., 2002, J. Immunol. 169:350-8) or adenoviral vectors expressing HPV16-E2E6E7SH, a marked decrease of the growth of TC-1 induced tumors was observed (FIGS. 12B and 12C). Closer inspection of the first 30 days after the prime immunizations (FIGS. 12F and 12G) shows that the immunization with the adenovectors expressing E2E6E7SH have a substantially larger impact on tumor growth than immunization with the SLPs. The initial growth rate is much lower and in most cases the tumors shrunk. In 3 out of 11 mice immunized with the adenoviral vectors, the tumors were completely eradicated, which is reflected in the survival plot (FIG. 12H).

In conclusion, immunization with adenoviral vectors expressing a polypeptide of the disclosure significantly reduced tumor growth or completely eradicated established tumors in a well-established challenge model for HPV16-induced cancer.

Example 6 Employment of Repressor Systems to Improve the Productivity and Genetic Stability of Adenoviral Vectors Expressing HPV-Derived Antigens

It has previously been reported that transgenes inserted into adenovirus vectors under the control of powerful constitutively active promoters can, depending on the properties of the transgene product, negatively impact vector production (Yoshida and Yamada, 1997, Biochem. Biophys. Res. Commun. 230:426-30; Rubinchik et al., 2000, Gene Ther. 7:875-85; Matthews et al., 1999, J. Gen. Virol. 80:345-53; Edholm et al., 2001, J. Virol. 75:9579-84; Gall et al., 2007, Mol. Biotechnol. 35:263-73). Examples of transgene-dependent vector productivity issues include inefficient vector rescue and growth, low final vector yields, and, in severe cases, rapid outgrowth of viral mutants with defective transgene cassettes. To solve these issues, multiple studies explored the possibility to silence vector transgene expression during vector replication in producer cells (Matthews et al., 1999, J. Gen. Virol. 80:345-53; Edholm et al., 2001, J. Virol. 75:9579-84; Gall et al., 2007, Mol. Biotechnol. 35:263-73; Cottingham et al., 2012, Biotechnol. Bioeng. 109:719-28; Gilbert et al., 2014, J. Virol. Methods 208:177-88). In this regard, different repression systems have previously been implemented in the context of Ad vectors and have indeed shown to improve vector productivity and genetic stability for vectors encoding different types of (inhibitory) transgenes.

It was observed that some of the adenovirus vectors described herein, as well as some other adenoviral vectors encoding certain HPV antigen variants, displayed some of the transgene-dependent vector productivity issues described above and, therefore, could possibly be further improved in that respect. We, therefore, sought to investigate whether usage of systems to repress vector transgene expression can improve production characteristics of Ad vectors expressing HPV-derived antigens as those described herein. For this purpose, we implemented two existing repressor-operator systems, i.e., TetR/TetO (Yao and Eriksson, 1999, Hum. Gene Ther. 10:419-22, EP0990041B1) and CymR/CuO (Mullick et al., 2006, BMC Biotechnol. 6:43), into our adenovirus vector platform. Both the TetR/TetO and the CymR/CuO system have previously been used by others to improve adenovirus vector productivity through vector transgene silencing during vector replication (Gall et al., 2007, Mol. Biotechnol. 35:263-73; Cottingham et al., 2012, Biotechnol. Bioeng. 109:719-28; Gilbert et al., 2014, J. Virol. Methods 208:177-88). Implementation of these two systems involved the generation of adenoviral vectors expressing genes of interest under the control of either a TetO or a CuO sequence-containing CMV promoter. Furthermore, the implementation entailed the generation of cell lines stably expressing the respective cognate repressors proteins (i.e., TetR or CymR).

Several E1-deleted, Ad26- and Ad35-based vectors were generated in which sequences encoding heterologous polypeptides were operably linked to a CMV promoter containing either TetO or CuO operator sequences. First, certain TetO- or CuO-containing sequences (SEQ ID NO:11 and SEQ ID NO:12, respectively) were inserted near the transcription start site (TSS) of the CMV promoter (SEQ ID NO:13) of pAdapt26 and pAdapt35.Bsu plasmids (Abbink et al., 2007, J. Virol. 81:4654-63; Havenga et al., 2006, J. Gen. Virol. 87:2135-43). The operator-containing sequences were inserted at precisely the same positions of the CMV promoter as previously described for the two systems (Yao and Eriksson, 1999, Human Gene Ther. 10:419-22; EP0990041B1; Mullick et al., 2006, BMC Biotechnol. 6:43; EP1385946B1). Specifically, relative to the TSS (as originally assigned; Stenberg et al., 1984, J. Virol. 49:190-9), the TetO- and CuO-containing sequences were inserted directly downstream of positions −20 and +7, respectively. In SEQ ID NO:13, these two positions correspond to positions 716 and 742, respectively. The resulting operator-containing CMV promoters are termed, respectively, CMVTetO and CMVCuO. Next, different transgenes were inserted downstream of the (modified) CMV promoters of the resulting constructs using HindIII and XbaI restriction sites. These transgenes included genes encoding a fusion protein of green fluorescent protein and luciferase (GFP-Luc), LSE2E6E7SH from the present disclosure, and another polypeptide with some similarity to LSE2E6E7SH (a construct referred to in this example as “HPVAg”). HPVAg comprises the same leader sequence as present in LSE2E6E7SH, as well as E2, E6, and E7 sequences of HPV16. Using methods as described herein, the resulting modified pAdapt26 and pAdapt35.Bsu plasmids were used for the generation of adenoviral vectors expressing the above mentioned reporter and HPV transgenes under the control of either the CMVTetO or the CMVCuO promoter.

Cell lines expressing either TetR or CymR were generated by stable transfection of PER.C6® cells using, respectively, plasmid pcDNA™6/TR (LifeTechnologies, V1025-20) and a derivative of pcDNA™6/TR in which the TetR-coding sequence (SEQ ID NO:14, which encodes polypeptide SEQ ID NO:15) is replaced by a codon-optimized CymR-coding sequence (SEQ ID NO:16, which encodes polypeptide SEQ ID NO:17). Stable cell line generation was performed largely as described by the supplier of pcDNA™6/TR using a transient transfection-based assay to screen for cell clones capable of repressing expression of CMVTetO- or CMVCuO-driven genes. The resulting PER.C6/TetR and PER.C6/CymR cell lines were analyzed for their ability to repress transgene expression during vector replication in these cells. Experiments conducted with vectors expressing GFP-Luc under the control of operator-containing CMV-promoters showed at least a ten-fold reduction of luciferase gene expression throughout the complete virus replication cycle in the cell lines expressing the repressor corresponding to the respective operator sequences (data not shown). This confirmed that the PER.C6/TetR and PER.C6/CymR cell lines were capable of repressing vector transgene expression in the context of replicating adenovirus vectors.

The effect of TetR- and CymR-mediated repression of adenovector transgene expression on vector yields was investigated for Ad35-based vectors expressing HPVAg (FIG. 13A). To this end, PER.C6®, PER.C6/TetR, and PER.C6/CymR cell lines, seeded at 3*10⁵ cells per well in 24-well plate wells, were subjected to quadruplicate infections—at 1000 virus particles per cell and for a duration of three hours—by vectors expressing HPVAg from either CMVTetO or CMVCuO promoters. As controls, parallel infections were performed with corresponding vectors expressing GFP-Luc instead of HPVAg. Four days after infection, crude viral lysates were prepared by subjecting the contents of the wells (i.e., infected cells and medium) to two freeze-thaw cycles. Adenovector titers were subsequently determined by an Ad35 hexon sequence-specific quantitative PCR-based protocol that uses a purified Ad35 vector with known virus particle titer as a standard. The results show that both the TetO- and the CuO-containing HPVAg-encoding Ad35 vectors, compared to the control vectors expressing GFP-Luc, display decreased vector yields on normal PER.C6® cells. By contrast, when produced on cells expressing their cognate repressors (i.e., TetR and CymR, respectively), these same vectors gave yields as high as those obtained with the control vectors. These data indicate that repression of transgene expression during vector production in producer cells can be beneficial for the productivity of Ad35 vectors carrying HPVAg as a transgene.

The effect that repression of adenovector transgene expression may have on vector yields was also investigated for vectors derived from adenovirus serotype 26 (Ad26) (FIG. 13B). In an assay performed essentially as described above for the Ad35 vectors, Ad26 vectors carrying CMVTetO promoter-controlled transgenes encoding either GFP-Luc, HPVAg, or LSE2E6E7SH were used to infect PER.C6® and PER.C6/TetR cells at 1500 virus particles per cell. Three days later the infections were harvested and virus particle titers determined by an Ad26 hexon sequence-specific quantitative PCR-based method. The results show that on PER.C6® cells the yields for the vectors encoding HPVAg and LSE2E6E7SH are lower than obtained with the control vector encoding GFP-Luc. In contrast, on PER.C6/TetR cells, both these vectors showed titers that are as high as that obtained for the control vector. Together with the results above (for Ad35 vectors), these data indicate that repression of transgene expression during adenovector production increases the yields of vectors expressing HPVAg and LSE2E6E7SH.

We have observed major issues regarding the genetic stability of an adenovirus vector that carried a CMV promoter-driven transgene for HPVAg. For example, it was observed that after several passaging rounds of this vector on PER.C6® the majority of the vector population consisted of a mutant vector that carried a large deletion in the HPVAg coding sequence (data not shown).

We reasoned that employment of a transgene expression repression system, such as one of the two described above, could prevent genetic stability issues associated with transgenes, such as HPVAg that are inhibitory to vector growth. To test this, an Ad35-based vector with CMVCuO promoter-driven HPVAg expression was assessed for transgene cassette stability upon growth of the vector on either PER.C6® or PER.C6/CymR cells (FIGS. 14A, and 14B). In brief, vector DNA was transfected into the two different cell lines and resultant viral plaques were allowed to grow under an agarose layer. From each of the two transfections, five viral plaques were isolated and separately passaged further on the same cell line (i.e., as used for the transfection), for ten consecutive viral passages. Transgene integrity was assessed by PCR amplification of the transgene cassette at viral passage number ten (VPN10), and the subsequent analysis of resultant PCR products by gel electrophoresis and Sanger sequencing. In addition, at VPN7, the passaged viral clones were assessed for their ability to express HPVAg. This was done by using the passaged viral isolates to infect A549 cells at 1000 virus particles per cell, lysing the cells at 48 hours post-infection, and subsequently analyzing the expression of HPVAg by western blotting using a monoclonal antibody directed against HPV16 E7 (Santa-Cruz Biotechnology). The results of the gel electrophoresis and sequencing analyses showed that all five viral isolates that had been passaged on PER.C6® each carried either small frameshifting deletions or premature stop mutations within the transgene cassette. By contrast, such deletions or mutations could not be detected in any of the vector isolates that had been passaged on the cell line expressing CymR (PER.C6/CymR). In agreement with these data, all PER.C6/CymR-propagated vector isolates were able to express HPVAg, while all PER.C6®-grown vectors completely lost this ability, suggesting defective transgene cassettes for these vectors. In conclusion, our data demonstrate that employment of a repressor system, as, for instance, the CymR/CuO system, to repress vector transgene expression during vector propagation is an effective means to prevent severe transgene cassette instability, such as that seen for vectors carrying a transgene expressing HPVAg.

REFERENCES (THE CONTENTS OF EACH OF WHICH ARE INCORPORATED HEREIN BY THIS REFERENCE)

-   -   Abbink P, A. A. Lemckert, B. A. Ewald, D. M. Lynch, M.         Denholtz, S. Smits, L. Holterman, I. Damen, R. Vogels, A. R.         Thorner, K. L. O'Brien, A. Carville, K. G. Mansfield, J.         Goudsmit, M. J. Havenga, and D. H. Barouch (2007). Comparative         seroprevalence and immunogenicity of six rare serotype         recombinant adenovirus vaccine vectors from subgroups B         and D. J. Virol. 81:4654-4663.     -   Ausubel F. M. (1995). Short protocols in molecular biology: a         compendium of methods from Current Protocols in Molecular         Biology. Wiley, [Chichester].     -   Cottingham M. G., F. Carroll, S. J. Morris, A. V. Turner, A. M.         Vaughan, M. C. Kapulu, S. Colloca, L. Siani, S. C. Gilbert,         and A. V. Hill (2012). Preventing spontaneous genetic         rearrangements in the transgene cassettes of adenovirus vectors.         Biotechnol. Bioeng. 109:719-728.     -   Daayana S., E. Elkord, U. Winters, M. Pawlita, R. Roden, P. L.         Stern, and H. C. Kitchener (2010). Phase II trial of imiquimod         and HPV therapeutic vaccination in patients with vulval         intraepithelial neoplasia. Br. J. Cancer 102:1129-1136.     -   de Jong A., S. H. van der Burg, K. M. Kwappenberg, J. M. van der         Hulst, K. L. Franken, A. Geluk, K. E. van Meijgaarden, J. W.         Drijfhout, G. Kenter, P. Vermeij, C. J. Melief, and R. Offringa         (2002). Frequent detection of human papillomavirus 16         E2-specific T-helper immunity in healthy subjects. Cancer Res.         62:472-479.     -   Edholm D., M. Molin, E. Bajak, and G. Akusjarvi (2001).         Adenovirus vector designed for expression of toxic proteins. J.         Virol. 75:9579-9584.     -   Evans R. K., D. K. Nawrocki, L. A. Isopi, D. M. Williams, D. R.         Casimiro, S. Chin, M. Chen, D. M. Zhu, J. W. Shiver, and D. B.         Volkin (2004). Development of stable liquid formulations for         adenovirus-based vaccines. J. Pharm. Sci. 93:2458-2475.     -   Fallaux F. J., A. Bout, I. van der Velde, D. J. van den         Wollenberg, K. M. Hehir, J. Keegan, C. Auger, S. J. Cramer, H.         van Ormondt, A. J. van der Eb, D. Valerio, and R. C. Hoeben         (1998). New helper cells and matched early region 1-deleted         adenovirus vectors prevent generation of replication-competent         adenoviruses. Hum. Gene Ther. 9:1909-1917.     -   Frøkjær S., and L. Hovgaard (2000). Pharmaceutical formulation         development of peptides and proteins. Taylor and Francis,         London.     -   Gall J. G., A. Lizonova, D. EttyReddy, D. McVey, M. Zuber, I.         Kovesdi, B. Aughtman, C. R. King, and D. E. Brough (2007).         Rescue and production of vaccine and therapeutic adenovirus         vectors expressing inhibitory transgenes. Mol. Biotechnol.         35:263-273.     -   Gao G. P., R. K. Engdahl, and J. M. Wilson (2000). A cell line         for high-yield production of E1-deleted adenovirus vectors         without the emergence of replication-competent virus. Hum. Gene         Ther. 11:213-219.     -   Gennaro A. R. (1990). Remington's Pharmaceutical Sciences. Mack     -   Gilbert R., C. Guilbault, D. Gagnon, A. Bernier, L.         Bourget, S. M. Elahi, A. Kamen, and B. Massie (2014).         Establishment and validation of new complementing cells for         production of E1-deleted adenovirus vectors in serum-free         suspension culture. J. Virol. Methods 208:177-188.     -   Hamid O., and R. D. Carvajal (2013). Anti-programmed death-1 and         anti-programmed death-ligand 1 antibodies in cancer therapy.         Expert Opin. Biol. Ther. 13:847-861.     -   Harlow E., and D. Lane (1988). Antibodies: A Laboratory Manual.         Cold Spring Harbor Laboratory, New York.     -   Havenga M., R. Vogels, D. Zuijdgeest, K. Radosevic, S.         Mueller, M. Sieuwerts, F. Weichold, I. Damen, J. Kaspers, A.         Lemckert, M. van Meerendonk, R. van der Vlugt, L. Holterman, D.         Hone, Y. Skeiky, R. Mintardjo, G. Gillissen, D. Barouch, J.         Sadoff, and J. Goudsmit (2006). Novel replication-incompetent         adenoviral B-group vectors: high vector stability and yield in         PER.C6® cells. J. Gen. Virol. 87:2135-2143.     -   Henken F. E., K. Oosterhuis, P. Ohlschlager, L. Bosch, E.         Hooijberg, J. B. Haanen, and R. D. Steenbergen (2012).         Preclinical safety evaluation of DNA vaccines encoding modified         HPV16 E6 and E7. Vaccine 30:4259-4266.     -   Hildesheim A., R. Herrero, S. Wacholder, A.C. Rodriguez, D.         Solomon, M. C. Bratti, J. T. Schiller, P. Gonzalez, G. Dubin, C.         Porras, S. E. Jimenez, and D. R. Lowy (2007). Effect of human         papillomavirus 16/18 L1 virus-like particle vaccine among young         women with preexisting infection: a randomized trial. JAMA         298:743-753.     -   Hoganson D. K., J. C. Ma, L. Asato, M. Ong, M. A. Printz, B. G.         Huyghe, B. A. Sosnowshi, and M. J. D'Andrea (2002). Development         of a stable adenoviral vector formulation. Bioprocess J.         1:43-48.

Hoof I., B. Peters, J. Sidney, L. E. Pedersen, A. Sette, O. Lund, S. Buus, and M. Nielsen (2009). NetMHCpan, a method for MHC class I binding prediction beyond humans. Immunogenetics 61:1-13.

-   -   Horwitz M. S. (1996). “Adenoviruses” in B. N. Fields, D. M.         Knipe, J. D. Baines (eds.), Virology. Raven Press Ltd, New York.     -   Kenter G. G., M. J. Welters, A. R. Valentijn, M. J. Lowik, D. M.         Berends-van der Meer, A. P. Vloon, F. Essahsah, L. M.         Fathers, R. Offringa, J. W. Drijfhout, A. R. Wafelman, J.         Oostendorp, G. J. Fleuren, S. H. van der Burg, and C. J. Melief         (2009). Vaccination against HPV-16 oncoproteins for vulvar         intraepithelial neoplasia. N. Engl. J. Med. 361:1838-1847.     -   Kibbe A. H. (2000). Handbook of Pharmaceutical Excipients.         Pharmaceutical Press, London. Kovesdi I., and S. J. Hedley         (2010). Adenoviral producer cells, Viruses 2:1681-1703.     -   Lin K. Y., F. G. Guarnieri, K. F. Staveley-O'Carroll, H. I.         Levitsky, J. T. August, D. M. Pardoll, and T. C. Wu (1996).         Treatment of established tumors with a novel vaccine that         enhances major histocompatibility class II presentation of tumor         antigen. Cancer Res. 56:21-26.     -   Lundegaard C., K. Lamberth, M. Harndahl, S. Buus, O. Lund,         and M. Nielsen (2008). NetMHC-3.0: accurate web accessible         predictions of human, mouse and monkey MHC class I affinities         for peptides of length 8-11. Nucleic Acids Res. 36:W509-512.     -   Massimi P., and L. Banks (2005). “Transformation Assays for HPV         Oncoproteins” in C. Davy, J. Doorbar (eds.), Human         Papillomaviruses: Methods and Protocols, Vol 119: Methods in         Molecular Medicine. Springer, Berlin, pp. 381-395.     -   Matthews D. A., D. Cummings, C. Evelegh, F. L. Graham, and L.         Prevec (1999). Development and use of a 293 cell line expressing         lac repressor for the rescue of recombinant adenoviruses         expressing high levels of rabies virus glycoprotein. J. Gen.         Virol. 80 (Pt 2):345-353.     -   McPherson M. J., B. D. Hames, G. R. Taylor (1995). PCR 2: A         Practical Approach. IRL Press at Oxford University Press,         Oxford.     -   Mellman I., G. Coukos, and G. Dranoff (2011). Cancer         immunotherapy comes of age. Nature 480:480-489.     -   Mullick A., Y. Xu, R. Warren, M. Koutroumanis, C. Guilbault, S.         Broussau, F. Malenfant, L. Bourget, L. Lamoureux, R. Lo, A. W.         Caron, A. Pilotte, and B. Massie (2006). The cumate gene-switch:         a system for regulated expression in mammalian cells. BMC         Biotechnol. 6:43.     -   Munger K., W. C. Phelps, V. Bubb, P. M. Howley, and R. Schlegel         (1989). The E6 and E7 genes of the human papillomavirus type 16         together are necessary and sufficient for transformation of         primary human keratinocytes. J. Virol. 63:4417-4421.     -   Ogun S. A., L. Dumon-Seignovert, J. B. Marchand, A. A. Holder,         and F. Hill (2008). The oligomerization domain of C4-binding         protein (C4bp) acts as an adjuvant, and the fusion protein         comprised of the 19-kilodalton merozoite surface protein 1 fused         with the murine C4bp domain protects mice against malaria.         Infect. Immun. 76:3817-3823.     -   Oosterhuis K., E. Aleyd, K. Vrijland, T. N. Schumacher,         and J. B. Haanen (2012a). Rational Design of DNA Vaccines for         the Induction of Human Papillomavirus Type 16 E6- and         E7-Specific Cytotoxic T-Cell Responses. Hum. Gene Ther.         23:1301-1312.     -   Oosterhuis K., P. Ohlschlager, J. H. van den Berg, M. Toebes, R.         Gomez, T. N. Schumacher, and J. B. Haanen (2011). Preclinical         development of highly effective and safe DNA vaccines directed         against HPV 16 E6 and E7. Int. J. Cancer 129:397-406.     -   Oosterhuis K., J. H. van den Berg, T. N. Schumacher, and J. B.         Haanen (2012b). DNA vaccines and intradermal vaccination by DNA         tattooing. Curr. Top Microbiol. Immunol. 351:221-250.     -   Peters B., W. Tong, J. Sidney, A. Sette, and Z. Weng (2003).         Examining the independent binding assumption for binding of         peptide epitopes to MHC-I molecules. Bioinformatics         19:1765-1772.     -   Prakash S. S., S. R. Grossman, R. B. Pepinsky, L. A. Laimins,         and E. J. Androphy (1992). Amino acids necessary for DNA contact         and dimerization imply novel motifs in the papillomavirus E2         trans-activator. Genes Dev. 6:105-116.     -   Rubinchik S., R. Ding, A. J. Qiu, F. Zhang, and J. Dong (2000).         Adenoviral vector which delivers FasL-GFP fusion protein         regulated by the tet-inducible expression system. Gene Ther.         7:875-885.     -   Sambrook JFEFMT (1989). Molecular cloning: A Laboratory Manual.         Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.     -   Sedman S. A., M. S. Barbosa, W. C. Vass, N. L. Hubbert, J. A.         Haas, D. R. Lowy, and J. T. Schiller (1991). The full-length E6         protein of human papillomavirus type 16 has transforming and         trans-activating activities and cooperates with E7 to         immortalize keratinocytes in culture. J. Virol. 65:4860-4866.     -   Shenk T. (1996). “Adenoviridae and their Replication” in B. N.         Fields, D. M. Knipe, and J. D. Baines (eds.), Virology. Raven         Press Ltd, New York.     -   Smahel M., P. Sima, V. Ludvikova, and V. Vonka (2001). Modified         HPV16 E7 Genes as DNA Vaccine against E7-Containing Oncogenic         Cells. Virology 281:231-238.     -   van der Burg S. H., and C. J. Melief (2011). Therapeutic         vaccination against human papilloma virus induced malignancies.         Curr. Opin. Immunol. 23:252-257.     -   Watson J. D. (1992). Recombinant DNA. Scientific American Books,         New York.     -   Wieking B. G., D. W. Vermeer, W. C. Spanos, K. M. Lee, P.         Vermeer, W. T. Lee, Y. Xu, E. S. Gabitzsch, S. Balcaitis, J. P.         Balint, Jr., F. R. Jones, and J. H. Lee (2012). A non-oncogenic         HPV 16 E6/E7 vaccine enhances treatment of HPV expressing         tumors. Cancer Gene Ther. 19:667-674.     -   Yan J., D. K. Reichenbach, N. Corbitt, D. A. Hokey, M. P.         Ramanathan, K. A. McKinney, D. B. Weiner, and D. Sewell (2009).         Induction of antitumor immunity in vivo following delivery of a         novel HPV-16 DNA vaccine encoding an E6/E7 fusion antigen.         Vaccine 27:431-440.     -   Yao F., and E. Eriksson (1999). A novel tetracycline-inducible         viral replication switch. Hum. Gene Ther. 10:419-427.     -   Yoshida Y., and H. Hamada (1997). Adenovirus-mediated inducible         gene expression through tetracycline-controllable transactivator         with nuclear localization signal. Biochem. Biophys. Res. Commun.         230:426-430.     -   Yugawa T., and T. Kiyono (2009). Molecular mechanisms of         cervical carcinogenesis by high-risk human papillomaviruses:         novel functions of E6 and E7 oncoproteins. Rev. Med. Virol.         19:97-113.     -   Zwaveling S., S. C. Ferreira Mota, J. Nouta, M. Johnson, G. B.         Lipford, R. Offringa, S. H. van der Burg, and C. J. Melief         (2002). Established human papillomavirus type 16-expressing         tumors are effectively eradicated following vaccination with         long peptides. J. Immunol. 169:350-358.

TABLE I sequences (HPV16-E6E7SH, amino acid sequence of HPV16 E6/E7 designer polypeptide) SEQ ID NO: 1 MHQKRTAMFQ DPQERPRKLP QLCTELQTTI HDIILECVYC KQQLEDEIDG PAGQAEPDRA HYNIVTFCCK CDSTLRLCVQ STHVDIRTLE DLLMGTLGIV CPICSQKPGT TLEQQYNKPL CDLLIRCINC QKPLCPEEKQ RHLDKKQRFH NIRGRWTGRC MSCCRSSRTR RETQMHGDTP TLHEYMLDLQ PETTDLYCYE QLNDSSEEED EIDGPAGQAE PDRAHYNIVT FCCQLCTELQ TTIHDIILEC VYCKQQLLRR EVYDFAFRDL CIVYRDGNPY AVCDKCLKFY SKISEYRHYC YSLYGTTLEQ QYNKPLCDLL IRCINCQK (HPV16-E6E7SH, nucleotide sequence encoding amino acid sequence of HPV16 E6/E7 designer polypeptide) SEQ ID NO: 2 ATGCACCAGA AACGGACCGC CATGTTCCAG GACCCCCAGG AACGGCCCAG AAAGCTGCCC CAGCTGTGCA CCGAGCTGCA GACCACCATC CACGACATCA TCCTGGAATG CGTGTACTGC AAGCAGCAGC TGGAAGATGA GATCGACGGC CCTGCTGGCC AGGCCGAACC CGACAGAGCC CACTACAATA TCGTGACCTT CTGCTGCAAG TGCGACAGCA CCCTGCGGCT GTGCGTGCAG AGCACCCACG TGGACATCCG GACCCTGGAA GATCTGCTGA TGGGCACCCT GGGCATCGTG TGCCCCATCT GCAGCCAGAA GCCCGGCACC ACCCTGGAAC AGCAGTACAA CAAGCCCCTG TGCGACCTGC TGATCCGGTG CATCAACTGC CAGAAACCCC TGTGCCCCGA GGAAAAGCAG CGGCACCTGG ACAAGAAGCA GCGGTTCCAC AACATCCGGG GCAGATGGAC AGGCAGATGC ATGAGCTGCT GCAGAAGCAG CCGGACCAGA CGGGAAACCC AGATGCACGG CGACACCCCC ACCCTGCACG AGTACATGCT GGACCTGCAG CCCGAGACAA CCGACCTGTA CTGCTACGAG CAGCTGAACG ACAGCAGCGA GGAAGAGGAC GAGATTGACG GACCCGCTGG ACAGGCCGAG CCTGACCGGG CTCACTATAA CATCGTGACA TTTTGCTGTC AGCTCTGTAC TGAACTCCAG ACAACAATTC ACGATATTAT TCTCGAATGT GTGTATTGTA AACAGCAGCT CCTGCGGAGA GAGGTGTACG ACTTCGCCTT CCGGGACCTC TGCATCGTGT ATCGGGACGG CAACCCCTAC GCCGTGTGCG ACAAGTGCCT GAAGTTCTAC AGCAAGATCA GCGAGTACCG GCACTACTGC TACAGCCTGT ACGGAACAAC ACTCGAACAG CAGTATAACA AACCACTCTG TGATCTGCTG ATTCGCTGTA TCAATTGTCA GAAGTGATAA (HPV16 E2E6E7SH, amino acid sequence of HPV16 E2/E6/E7 designer polypeptide) SEQ ID NO: 3 METLCQRLNVCQDKILTHYENDSTDLRDHIDYWKHMRLECAIYYKAREMGFKHINHQVVPTLAV SKNKALQAIELQLTLETIYNSQYSNEKWTLQDVSLEVYLTAPTGCIKKHGYTVEVQFDGDICNT MHYTNWTHIYICEEASVTVVEGQVDYYGLYYVHEGIRTYFVQFKDDAEKYSKNKVWEVHAGGQV ILCPTSVFSSNEVSSPEIIRQHLANHPAATHTKAVALGTEETQTTIQRPRSEPDTGNPCHTTKL LHRDSVDSAPILTAFNSSHKGRINCNSNTTPIVHLKVDANTLMRLRYRFKKHCTLYTAVSSTWH WTGHNVKHKSAIVTLTYDSEWQRDQFLSQVKIPKTITVSTGFMSIMHQKRTAMFQDPQERPRKL PQLCTELQTTIHDIILECVYCKQQLEDEIDGPAGQAEPDRAHYNIVTFCCKCDSTLRLCVQSTH VDIRTLEDLLMGTLGIVCPICSQKPGTTLEQQYNKPLCDLLIRCINCQKPLCPEEKQRHLDKKQ RFHNIRGRWTGRCMSCCRSSRTRRETQMHGDTPTLHEYMLDLQPETTDLYCYEQLNDSSEEEDE IDGPAGQAEPDRAHYNIVTFCCQLCTELQTTIHDIILECVYCKQQLLRREVYDFAFRDLCIVYR DGNPYAVCDKCLKFYSKISEYRHYCYSLYGTTLEQQYNKPLCDLLIRCINCQK (HPV16 E2E6E7SH, nucleotide sequence encoding HPV16 E2/E6/E7 designer polypeptide SEQ ID NO: 4 ATGGAAACCCTGTGCCAGCGGCTGAACGTGTGCCAGGACAAGATCCTGACCCACTACGAGAACG ACAGCACCGACCTGCGGGACCACATCGACTACTGGAAGCACATGCGGCTGGAATGCGCCATCTA CTACAAGGCCAGAGAGATGGGCTTCAAGCACATCAACCACCAGGTGGTGCCCACCCTGGCCGTG TCCAAGAACAAGGCCCTGCAGGCCATCGAGCTGCAGCTGACCCTGGAAACCATCTACAACAGCC AGTACAGCAACGAGAAGTGGACCCTGCAGGACGTGTCCCTGGAAGTGTACCTGACCGCTCCCAC CGGCTGCATCAAGAAACACGGCTACACCGTGGAAGTGCAGTTCGACGGCGACATCTGCAACACC ATGCACTACACCAACTGGACCCACATCTACATCTGCGAAGAGGCCAGCGTGACCGTGGTGGAAG GCCAGGTGGACTACTACGGCCTGTACTACGTGCACGAGGGCATCCGGACCTACTTCGTGCAGTT CAAGGACGACGCCGAGAAGTACAGCAAGAACAAAGTGTGGGAGGTGCACGCTGGCGGCCAGGTC ATCCTGTGCCCCACCAGCGTGTTCAGCAGCAACGAGGTGTCCAGCCCCGAGATCATCCGGCAGC ACCTGGCCAATCACCCTGCCGCCACCCACACAAAGGCCGTGGCCCTGGGCACCGAGGAAACCCA GACCACCATCCAGCGGCCCAGAAGCGAGCCCGACACCGGCAATCCCTGCCACACCACCAAGCTG CTGCACCGGGACAGCGTGGACAGCGCCCCTATCCTGACCGCCTTCAACAGCAGCCACAAGGGCC GGATCAACTGCAACAGCAACACCACCCCCATCGTGCACCTGAAGGTGGACGCCAACACCCTGAT GCGGCTGCGGTACAGATTCAAGAAGCACTGCACCCTGTACACCGCCGTGTCCTCCACCTGGCAC TGGACCGGCCACAACGTGAAGCACAAGAGCGCCATCGTGACCCTGACCTACGACAGCGAGTGGC AGCGGGACCAGTTCCTGAGCCAGGTCAAAATCCCCAAGACCATCACCGTGTCCACCGGCTTCAT GAGCATCATGCACCAGAAACGGACCGCCATGTTCCAGGACCCCCAGGAACGGCCCAGAAAGCTG CCCCAGCTGTGCACCGAGCTGCAGACCACCATCCACGACATCATCCTGGAATGCGTGTACTGCA AGCAGCAGCTGGAAGATGAGATCGACGGCCCTGCTGGCCAGGCCGAACCCGACAGAGCCCACTA CAATATCGTGACCTTCTGCTGCAAGTGCGACAGCACCCTGCGGCTGTGCGTGCAGAGCACCCAC GTGGACATCCGGACCCTGGAAGATCTGCTGATGGGCACCCTGGGCATCGTGTGCCCCATCTGCA GCCAGAAGCCCGGCACCACCCTGGAACAGCAGTACAACAAGCCCCTGTGCGACCTGCTGATCCG GTGCATCAACTGCCAGAAACCCCTGTGCCCCGAGGAAAAGCAGCGGCACCTGGACAAGAAGCAG CGGTTCCACAACATCCGGGGCAGATGGACAGGCAGATGCATGAGCTGCTGCAGAAGCAGCCGGA CCAGACGGGAAACCCAGATGCACGGCGACACCCCCACCCTGCACGAGTACATGCTGGACCTGCA GCCCGAGACAACCGACCTGTACTGCTACGAGCAGCTGAACGACAGCAGCGAGGAAGAGGACGAG ATTGACGGACCCGCTGGACAGGCCGAGCCTGACCGGGCTCACTATAACATCGTGACATTTTGCT GTCAGCTCTGTACTGAACTCCAGACAACAATTCACGATATTATTCTCGAATGTGTGTATTGTAA ACAGCAGCTCCTGCGGAGAGAGGTGTACGACTTCGCCTTCCGGGACCTCTGCATCGTGTATCGG GACGGCAACCCCTACGCCGTGTGCGACAAGTGCCTGAAGTTCTACAGCAAGATCAGCGAGTACC GGCACTACTGCTACAGCCTGTACGGAACAACACTCGAACAGCAGTATAACAAACCACTCTGTGA TCTGCTGATTCGCTGTATACATTGTCAGAAGTGATAA (HPV16 E6E7E2SH, encoding HPV16 E6/E7/E2 designer polypeptide SEQ ID NO: 5 MHQKRTAMFQDPQERPRKLPQLCTELQTTIHDIILECVYCKQQLEDEIDGPAGQAEPDRAHYNI VTFCCKCDSTLRLCVQSTHVDIRTLEDLLMGTLGIVCPICSQKPGTTLEQQYNKPLCDLLIRCI NCQKPLCPEEKQRHLDKKQRFHNIRGRWTGRCMSCCRSSRTRRETQMHGDTPTLHEYMLDLQPE TTDLYCYEQLNDSSEEEDEIDGPAGQAEPDRAHYNIVTFCCQLCTELQTTIHDIILECVYCKQQ LLRREVYDFAFRDLCIVYRDGNPYAVCDKCLKFYSKISEYRHYCYSLYGTTLEQQYNKPLCDLL IRCINCQKMETLCQRLNVCQDKILTHYENDSTDLRDHIDYWKHMRLECAIYYKAREMGFKHINH QVVPTLAVSKNKALQAIELQLTLETIYNSQYSNEKWTLQDVSLEVYLTAPTGCIKKHGYTVEVQ FDGDICNTMHYTNWTHIYICEEASVTVVEGQVDYYGLYYVHEGIRTYFVQFKDDAEKYSKNKVW EVHAGGQVILCPTSVFSSNEVSSPEIIRQHLANHPAATHTKAVALGTEETQTTIQRPRSEPDTG NPCHTTKLLHRDSVDSAPILTAFNSSHKGRINCNSNTTPIVHLKVDANTLMRLRYRFKKHCTLY TAVSSTWHWTGHNVKHKSAIVTLTYDSEWQRDQFLSQVKIPKTITVSTGFMSI (HPV16 E6E7E2SH, nucleotide sequence encoding HPV16 E6/E7/E2 designer polypeptide SEQ ID NO: 6 ATGCACCAGAAACGGACCGCCATGTTCCAGGACCCCCAGGAACGGCCCAGAAAGCTGCCCCAGC TGTGCACCGAGCTGCAGACCACCATCCACGACATCATCCTGGAATGCGTGTACTGCAAGCAGCA GCTGGAAGATGAGATCGACGGCCCTGCTGGCCAGGCCGAACCCGACAGAGCCCACTACAATATC GTGACCTTCTGCTGCAAGTGCGACAGCACCCTGCGGCTGTGCGTGCAGAGCACCCACGTGGACA TCCGGACCCTGGAAGATCTGCTGATGGGCACCCTGGGCATCGTGTGCCCCATCTGCAGCCAGAA GCCCGGCACCACCCTGGAACAGCAGTACAACAAGCCCCTGTGCGACCTGCTGATCCGGTGCATC AACTGCCAGAAACCCCTGTGCCCCGAGGAAAAGCAGCGGCACCTGGACAAGAAGCAGCGGTTCC ACAACATCCGGGGCAGATGGACAGGCAGATGCATGAGCTGCTGCAGAAGCAGCCGGACCAGACG GGAAACCCAGATGCACGGCGACACCCCCACCCTGCACGAGTACATGCTGGACCTGCAGCCCGAG ACAACCGACCTGTACTGCTACGAGCAGCTGAACGACAGCAGCGAGGAAGAGGACGAGATTGACG GACCCGCTGGACAGGCCGAGCCTGACCGGGCTCACTATAACATCGTGACATTTTGCTGTCAGCT CTGTACTGAACTCCAGACAACAATTCACGATATTATTCTCGAATGTGTGTATTGTAAACAGCAG CTCCTGCGGAGAGAGGTGTACGACTTCGCCTTCCGGGACCTCTGCATCGTGTATCGGGACGGCA ACCCCTACGCCGTGTGCGACAAGTGCCTGAAGTTCTACAGCAAGATCAGCGAGTACCGGCACTA CTGCTACAGCCTGTACGGAACAACACTCGAACAGCAGTATAACAAACCACTCTGTGATCTGCTG ATTCGCTGTATCAATTGTCAGAAGATGGAAACCCTGTGCCAGCGGCTGAACGTGTGCCAGGACA AGATCCTGACCCACTACGAGAACGACAGCACCGACCTGCGGGACCACATCGACTACTGGAAGCA CATGCGGCTGGAATGCGCCATCTACTACAAGGCCAGAGAGATGGGCTTCAAGCACATCAACCAC CAGGTGGTGCCCACCCTGGCCGTGTCCAAGAACAAGGCCCTGCAGGCCATCGAGCTGCAGCTGA CCCTGGAAACCATCTACAACAGCCAGTACAGCAACGAGAAGTGGACCCTGCAGGACGTGTCCCT GGAAGTGTACCTGACCGCTCCCACCGGCTGCATCAAGAAACACGGCTACACCGTGGAAGTGCAG TTCGACGGCGACATCTGCAACACCATGCACTACACCAACTGGACCCACATCTACATCTGCGAAG AGGCCAGCGTGACCGTGGTGGAAGGCCAGGTGGACTACTACGGCCTGTACTACGTGCACGAGGG CATCCGGACCTACTTCGTGCAGTTCAAGGACGACGCCGAGAAGTACAGCAAGAACAAAGTGTGG GAGGTGCACGCTGGCGGCCAGGTCATCCTGTGCCCCACCAGCGTGTTCAGCAGCAACGAGGTGT CCAGCCCCGAGATCATCCGGCAGCACCTGGCCAATCACCCTGCCGCCACCCACACAAAGGCCGT GGCCCTGGGCACCGAGGAAACCCAGACCACCATCCAGCGGCCCAGAAGCGAGCCCGACACCGGC AATCCCTGCCACACCACCAAGCTGCTGCACCGGGACAGCGTGGACAGCGCCCCTATCCTGACCG CCTTCAACAGCAGCCACAAGGGCCGGATCAACTGCAACAGCAACACCACCCCCATCGTGCACCT GAAGGTGGACGCCAACACCCTGATGCGGCTGCGGTACAGATTCAAGAAGCACTGCACCCTGTAC ACCGCCGTGTCCTCCACCTGGCACTGGACCGGCCACAACGTGAAGCACAAGAGCGCCATCGTGA CCCTGACCTACGACAGCGAGTGGCAGCGGGACCAGTTCCTGAGCCAGGTCAAAATCCCCAAGAC CATCACCGTGTCCACCGGCTTCATGAGCATCTGATAA (IgE leader peptide amino acid sequence) SEQ ID NO: 7 MDWTWILFLVAAATRVHS (nucleotide sequence encoding IgE leader peptide) SEQ ID NO: 8 ATGGACTGGACCTGGATCCTGTTCCTGGTGGCTGCCGCAACCCGGGTGCACAGC (aa HAVT20 leader peptide amino acid sequence) SEQ ID NO: 9 MACPGFLWALVISTCLEFSMA (nucleotide sequence encoding HAVT20 leader peptide) SEQ ID NO: 10 ATGGCCTGCCCCGGCTTTCTGTGGGCCCTGGTCATCAGCACCTGTCTGGAATTCAGCATGGCC (2xTetO-containing sequence) SEQ ID NO: 11 GAGCTCTCCCTATCAGTGATAGAGATCTCCCTATCAGTGATAGAGATCGTCGAC (CuO-containing sequence) SEQ ID NO: 12 AACAAACAGACAATCTGGTCTGTTTGTA (CMV promoter present in pAdApt26 and pAdApt35 plasmids) SEQ ID NO: 13 TCAATATTGGCCATTAGCCATATTATTCATTGGTTATATAGCATAAATCAATATTGGCTATTGG CCATTGCATACGTTGTATCCATATCATAATATGTACATTTATATTGGCTCATGTCCAACATTAC CGCCATGTTGACATTGATTATTGACTAGTTATTAATAGTAATCAATTACGGGGTCATTAGTTCA TAGCCCATATATGGAGTTCCGCGTTACATAACTTACGGTAAATGGCCCGCCTGGCTGACCGCCC AACGACCCCCGCCCATTGACGTCAATAATGACGTATGTTCCCATAGTAACGCCAATAGGGACTT TCCATTGACGTCAATGGGIGGAGTATTTACGGTAAACTGCCCACTIGGCAGTACATCAAGIGTA TCATATGCCAAGTACGCCCCCTATTGACGTCAATGACGGTAAATGGCCCGCCIGGCATTATGCC CAGTACATGACCTTATGGGACTTTCCTACTTGGCAGTACATCTACGTATTAGTCATCGCTATTA CCATGGTGATGCGGTTTTGGCAGTACATCAATGGGCGTGGATAGCGGTTTGACTCACGGGGATT TCCAAGTCTCCACCCCATTGACGTCAATGGGAGTTTGTTTTGGCACCAAAATCAACGGGACTTT CCAAAATGTCGTAACAACTCCGCCCCATTGACGCAAATGGGCGGTAGGCGTGTACGGTGGGAGG TCTATATAAGCAGAGCTCGTTTAGTGAACCGTCAGATCGCCTGGAGACGCCATCCACGCTGTTT TGACCTCCATAGAAGACACCGGGACCGATCCAGCCTCCGCGGCCGGGAACGGTGCATTGGA (TetR, nucleotide sequence encoding amino acid sequence of TetR polypeptide expressed by pcDNA™6/TR) SEQ ID NO: 14 ATGTCTAGATTAGATAAAAGTAAAGTGATTAACAGCGCATTAGAGCTGCTTAATGAGGTCGGAA TCGAAGGTTTAACAACCCGTAAACTCGCCCAGAAGCTAGGTGTAGAGCAGCCTACATTGTATTG GCATGTAAAAAATAAGCGGGCTTTGCTCGACGCCTTAGCCATTGAGATGTTAGATAGGCACCAT ACTCACTTTTGCCCTTTAGAAGGGGAAAGCTGGCAAGATTTTTTACGTAATAACGCTAAAAGTT TTAGATGTGCTTTACTAAGTCATCGCGATGGAGCAAAAGTACATTTAGGTACACGGCCTACAGA AAAACAGTATGAAACTCTCGAAAATCAATTAGCCTTTTTATGCCAACAAGGTTTTTCACTAGAG AATGCATTATATGCACTCAGCGCTGTGGGGCATTTTACTTTAGGTTGCGTATTGGAAGATCAAG AGCATCAAGTCGCTAAAGAAGAAAGGGAAACACCTACTACTGATAGTATGCCGCCATTATTACG ACAAGCTATCGAATTATTTGATCACCAAGGTGCAGAGCCAGCCTTCTTATTCGGCCTTGAATTG ATCATATGCGGATTAGAAAAACAACTTAAATGTGAAAGTGGGTCCGCGTACAGCGGATCCCGGG AATTCAGATCTTATTAA (TetR, amino acid sequence of TetR polypeptide expressed by pcDNA™6/TR) SEQ ID NO: 15 MSRLDKSKVINSALELLNEVGIEGLTTRKLAQKLGVEQPTLYWHVKNKRALLDALAIEMLDRHH THFCPLEGESWQDFLRNNAKSFRCALLSHRDGAKVHLGTRPTEKQYETLENQLAFLCQQGFSLE NALYALSAVGHFTLGCVLEDQEHQVAKEERETPTTDSMPPLLRQAIELFDHQGAEPAFLFGLEL IICGLEKQLKCESGSAYSGSREFRSY (CymR, nucleotide sequence encoding amino acid sequence of CymR polypeptide) SEQ ID NO: 16 ATGTCTCCCAAACGACGGACTCAAGCGGAAAGGGCAATGGAAACTCAGGGTAAGCTGATTGCCG CGGCTCTGGGAGTGCTGCGAGAGAAAGGGTATGCCGGGTTTCGCATAGCCGACGTTCCTGGAGC TGCAGGCGTAAGCAGAGGAGCCCAATCTCATCACTTTCCGACCAAGCTGGAGCTTTTGCTGGCT ACCTTCGAATGGCTGTACGAGCAGATCACGGAAAGGAGTCGTGCTAGGCTGGCCAAGCTGAAAC CCGAGGATGATGTCATTCAGCAGATGCTGGACGATGCAGCCGAGTTCTTCCTGGACGACGACTT CAGCATCAGTCTCGACCTCATCGTAGCCGCAGATCGCGATCCAGCTTTGCGCGAGGGCATACAG AGAACAGTCGAGCGGAATCGGTTTGTGGTGGAGGACATGTGGCTTGGTGTTCTGGTGAGCAGAG GCCTCTCACGGGATGATGCCGAGGACATCCTGTGGCTGATCTTTAACTCCGTCAGAGGGTTGGC AGTGAGGTCCCTTTGGCAGAAGGACAAAGAACGGTTTGAACGTGTGCGAAACTCAACACTCGAG ATTGCTAGGGAACGCTACGCCAAGTTCAAGAGATGA (CymR, amino acid sequence of CymR polypeptide) SEQ ID NO: 17 MSPKRRTQAERAMETQGKLIAAALGVLREKGYAGFRIADVPGAAGVSRGAQSHHFPTKLELLLA TFEWLYEQITERSRARLAKLKPEDDVIQQMLDDAAEFFLDDDFSISLDLIVAADRDPALREGIQ RTVERNRFVVEDMWLGVLVSRGLSRDDAEDILWLIFNSVRGLAVRSLWQKDKERFERVRNSTLE IARERYAKFKR (HPV16 E6, aa41-65) SEQ ID NO: 18 KQQLLRREVYDFAFRDLCIVYRDGN (HPV16 E7 aa 43-77) SEQ ID NO: 19 GQAEPDRAHYNIVTFCCKCDSTLRLCVQSTHVDIR 

What is claimed is:
 1. A composition for treating a subject having persistent HPV infection, the composition comprising: a. a first vaccine composition comprising a recombinant adenovirus vector comprising a first nucleic acid sequence encoding a first polypeptide comprising the amino acid sequence of SEQ ID NO: 1, wherein the first nucleic acid sequence is operably linked to a first promoter, and b. a second vaccine composition comprising a recombinant pox virus vector comprising a second nucleic acid sequence encoding a second polypeptide comprising the amino acid sequence of SEQ ID NO: 1, wherein the second nucleic acid sequence is operably linked to a second promoter; wherein one of the first vaccine composition and the second vaccine composition is administered to the subject for priming vaccination and the other is administered to the subject for boosting administration.
 2. The composition of claim 1, wherein the first vaccine composition is administered to the subject for priming vaccination and the second vaccine is administered to the subject for boosting administration.
 3. The composition of claim 1, wherein the second vaccine composition is administered to the subject for priming vaccination and the first vaccine is administered to the subject for boosting administration.
 4. The composition of claim 1, wherein the recombinant adenovirus vector of the first vaccine composition is a recombinant human adenovirus serotype 26 (Ad26) vector.
 5. The composition of claim 1, wherein the recombinant pox virus vector is a Modified Vaccinia Ankara (MVA) vector.
 6. The composition of claim 1, wherein the first and second polypeptides each independently further comprise a leader sequence.
 7. The composition of claim 1, wherein the first and second polypeptides each independently further comprise at least one epitope of a human papillomavirus (HPV) E2 protein.
 8. The composition of claim 7, wherein the first and second polypeptides each independently comprise an HPV16 E2 protein having a deletion or mutation in the DNA binding domain of the HPV16 E2 protein.
 9. The composition of claim 8, wherein the HPV16 E2 protein is fused to the N-terminus of the amino acid sequence of SEQ ID NO:
 1. 10. The composition of claim 8, wherein the HPV16 E2 protein is fused to the C-terminus of the amino acid sequence of SEQ ID NO:
 1. 11. The composition of claim 8, wherein the first and second polypeptides each independently comprise SEQ ID NO: 3 or SEQ ID NO:
 5. 12. The composition of claim 1, wherein the first and second nucleic acid molecules each independently comprise the polynucleotide sequence of SEQ ID NO: 2, SEQ ID NO: 4, or SEQ ID NO:
 6. 13. The composition of claim 1, wherein the first promoter is operably coupled to a repressor operator sequence, to which a repressor protein can bind in order to repress expression of the promoter in the presence of said repressor protein.
 14. The composition of claim 13, wherein the first promoter comprises a CMV promoter and a tetracyclin operon operator (TetO) sequence.
 15. A composition for treating a subject having persistent HPV infection, the composition comprising: a. a first vaccine composition comprising a recombinant human adenovirus serotype 26 (Ad26) vector comprising a first nucleic acid sequence encoding a first polypeptide comprising the amino acid sequence of SEQ ID NO: 1 and at least one epitope of a human papillomavirus (HPV) E2 protein, wherein the first nucleic acid sequence is operably linked to a first promoter, and b. a second vaccine composition comprising a Modified Vaccinia Ankara (MVA) vector comprising a second nucleic acid sequence encoding a second polypeptide comprising the amino acid sequence of SEQ ID NO: 1 and at least one epitope of a human papillomavirus (HPV) E2 protein, wherein the second nucleic acid sequence is operably linked to a second promoter; wherein the first vaccine composition and the second vaccine composition is administered to the subject for priming vaccination and the second vaccine composition is administered to the subject for boosting administration.
 16. The composition of claim 15, wherein the first and second polypeptides each further independently comprise a leader sequence.
 17. The composition of claim 15, wherein the first and second polypeptides each independently comprise an HPV16 E2 protein having a deletion or mutation in the DNA binding domain of the HPV16 E2 protein.
 18. The composition of claim 17, wherein the first and second polypeptides each independently comprise SEQ ID NO: 3 or SEQ ID NO:
 5. 19. The composition of claim 15, wherein the first and second nucleic acid molecules each independently comprise the polynucleotide sequence of SEQ ID NO: 2, SEQ ID NO: 4, or SEQ ID NO:
 6. 20. The composition of claim 15, wherein the first promoter comprises a CMV promoter and a tetracyclin operon operator (TetO) sequence. 